Building integrated photovoltaic roofing assemblies and associated systems and methods

ABSTRACT

Building integrated photovoltaic (BIPV) systems provide for solar panel arrays that can be aesthetically pleasing and appear seamless to an observer. BIPV systems can be incorporated as part of roof surfaces as built into the structure of the roof, flush or forming a substantively uniform plane with roof panels or other panels mimicking a solar panel appearance. Pans supporting BIPV solar panels can be coupled by standing seams, in both lateral and longitudinal directions, to other photovoltaic-supporting pans or pans supporting non-photovoltaic structures, having both functional and aesthetic advantages. In some configurations, adjacent photovoltaic modules may be oriented so that a boundary between an up-roof photovoltaic module and a down-roof photovoltaic module is not noticeable by observers positioned at typical viewing angles of the roof.

CROSS-REFERENCE TO RELATED APPLICATIONS

This claims the benefit of all of: U.S. Provisional Application No. 62/294,743, titled “BUILDING INTEGRATED PHOTOVOLTAIC ROOFING SYSTEM” and filed on Feb. 12, 2016; U.S. Provisional Application No. 62/308,828, titled “BUILDING INTEGRATED PHOTOVOLTAIC ROOFING SYSTEM” and filed on Mar. 15, 2016; U.S. Provisional Application No. 62/313,678, titled “BUILDING INTEGRATED PHOTOVOLTAIC ROOFING SYSTEM” and filed on Mar. 25, 2016; U.S. Provisional Application No. 62/354,599, titled “BUILDING INTEGRATED PHOTOVOLTAIC ROOFING ASSEMBLIES AND ASSOCIATED SYSTEMS AND METHODS” and filed on Jun. 24, 2016; U.S. Provisional Application No. 62/357,329, titled “BUILDING INTEGRATED PHOTOVOLTAIC ROOFING ASSEMBLIES AND ASSOCIATED SYSTEMS AND METHODS” and filed on Jun. 30, 2016; and U.S. Provisional Application No. 62/374,704, titled “BUILDING INTEGRATED PHOTOVOLTAIC ROOFING ASSEMBLIES AND ASSOCIATED SYSTEMS AND METHODS” and filed on Aug. 12, 2016, which are all herein incorporated by reference in their entireties. This is also related to concurrently filed non-provisional applications U.S. Ser. Nos. 15/246,475 and 15/246,486, both titled “BUILDING INTEGRATED PHOTOVOLTAIC ROOFING ASSEMBLIES AND ASSOCIATED SYSTEMS AND METHODS”, filed on the same day as this paper, and which are both herein incorporated by reference in their entireties.

TECHNICAL FIELD

This generally relates to photovoltaic arrays.

BACKGROUND

Solar is becoming increasingly popular in the United States and abroad, but penetration remains relatively low versus the number of homes that could benefit from solar. The price per kilowatt for solar is now competitive with or below that of utility power in most areas, however, solar largely remains a niche product for those who value saving money, reducing CO₂ emissions, or both.

One factor that may limit the adoption of solar technology is aesthetics. Most residential solar systems are installed as modules on an existing tile or composition shingle roof. The solar array, which often only covers a portion of the roof, or even a portion of one mounting plane on the roof, stands out as separate and distinct from the existing roof, both in height and material. This structure is therefore visible even from the street level and over large distances.

Another obstacle to solar adoption in existing homes is the dissonance between the age of the existing roof and the solar system, particularly where the existing roof is made from composition shingle. The expected life of a solar system and a composition shingle roof are both about 25 years depending on the local climate, but the existing roof may be several years, if not decades, into that lifespan when a prospective customer is contacted. So the customer may be presented with the dilemma of getting a new roof first, increasing the cost of going solar, or installing a 25-year solar system on a roof, which may have a relatively shorter remaining operational lifespan.

Accordingly, there is a need to resolve the dissonance between the expected life of the solar system and the remaining life of the roof that also blends in more aesthetically with the complete roof surface or at least the mounting plane and that doesn't require the prospective customer to pay for a new roof and a new solar system over that roof.

BRIEF SUMMARY

Various embodiments provide a new and improved approach to installing solar on existing roofs, and in particular, existing composition shingle roofs. Some fit over an existing composition shingle roof and/or other suitable roof surfaces (e.g., a metal seam roof, roof deck, underlayment or insulation layer). Some have improved aesthetics that reduce the visual differences between solar and non-solar portions of the roof. Some are more modular and/or simplify the replacement capability of individual photovoltaic (“PV”) modules of the system. In addition, some cost less to make and install compared to conventional solar systems. And some solar systems can be installed as a new roof rather than a re-roof or mounted to an existing roof. These and other embodiments are discussed in greater detail in the detailed description and drawing figures.

BRIEF DESCRIPTION OF THE DRAWINGS

Illustrative aspects of the present disclosure are described in detail below with reference to the following drawing figures. It is intended that that embodiments and figures disclosed herein are to be considered illustrative rather than restrictive

FIG. 1A is an example of a prior art photovoltaic array installed on a roof.

FIG. 1B is an exemplary prior art photovoltaic module.

FIG. 2A is a building integrated photovoltaic system according to various embodiments of the present technology.

FIG. 2B is an exemplary photovoltaic module usable with a building integrated photovoltaic system according to various embodiments of the present technology.

FIGS. 2C and 2D are exploded views of the PV module of FIG. 2B illustrating different layers of the PV module according to various embodiments of the present technology.

FIG. 3A is a partial cutaway view of a portion of a building integrated photovoltaic system according to various embodiments of the present technology.

FIG. 3B is a cross sectional view of a structurally integrated non-PV roof pan or panel configured in accordance with certain embodiments of the present technology.

FIG. 3C is a cross sectional view of a building integrated photovoltaic system according to various embodiments of the present technology.

FIG. 4A is a cross sectional, close up view of a portion of a building integrated photovoltaic system including seams that are coupled according to certain embodiments of the present technology.

FIG. 4B is a cross sectional view of a seam cover, seam clip, and standing seams according to certain embodiments of the present technology.

FIGS. 4C and 4D are cross sectional views of a building integrated photovoltaic system including seams that are coupled according to yet further embodiments of the present technology.

FIGS. 4E-4G further illustrate a seam clip configured in accordance with an embodiment of the present technology.

FIGS. 4H and 4I show spacing and a filling or wedge member between photovoltaic modules and proximate side walls, in accordance with aspects of the present technology.

FIGS. 5-9A are a perspective view, cross sectional front view, and various side views of a portion of a building integrated photovoltaic system according to other various embodiments of the present technology, and FIG. 9B illustrates a close-up view of an eave portion of a roof including a louvered vent portion configured in accordance with embodiments of the present technology.

FIGS. 10A-10H illustrates an example of an BIPV system installation on a building including one or more features or components (e.g., roofing components, transition pans, PV module assemblies, roof pans, underlayment layers), in whole or in part, according to various embodiments of the present technology.

FIGS. 11A-11H illustrate various views of a grounding clip according to certain embodiments of the present technology.

FIGS. 12A-12C illustrate various views of wiring caps and clips according to various embodiments of the present technology.

FIGS. 13A-13M illustrate various wiring systems, circuits, and pathways in accordance with various embodiments of the present technology.

FIGS. 14A-14G illustrate other wiring features and support pan structures in accordance with certain embodiments of the present technology.

FIGS. 15A-15D illustrate various views of a photovoltaic module pan assembly capable of supporting a heat transfer or phase change material usable with a building integrated photovoltaic system as described herein according to various embodiments of the present technology.

FIGS. 16A-16J are schematic wiring options for solar cell sections of a photovoltaic module accounting for shading caused by standing seams, in accordance with certain embodiments of the present technology.

FIG. 16K is an illustration of incident solar energy on a photovoltaic panel and standing seams on the longitudinal sides thereof.

FIG. 17 shows an embodiment of a PV column of a solar panel array, where the PV column is configured to take advantage of convection and related heat transfer, in accordance with certain embodiments of the present technology.

FIG. 18 shows a schematic representation of vent modules, in accordance with certain embodiments of the present technology.

FIG. 19 is a perspective view of a PV module pan assembly with stand-off features usable with building integrated photovoltaic systems in accordance with certain embodiments.

FIGS. 20A-20L are various views including top perspective, side, end, and exploded views of a PV module-pan assembly usable with building integrated photovoltaic systems according to various embodiments.

FIGS. 20M-20Q show mounting portions formed or secured along a rear or up-roof edge surface of a PV module pan according to various embodiments.

FIGS. 21A-21E show various views of an alternative embodiment for a pan of PV module-pan assembly according to various embodiments.

FIG. 22 shows an embodiment of a PV pan of PV module-pan assembly according to various embodiments.

FIGS. 23A-23E show various views of down-roof transition pans or non-PV pans that can be positioned at down-roof end portions of a column of PV module-pan assemblies according to various embodiments.

FIGS. 24A-24D show various views of up-roof transition or non-PV pans positioned over or mounted to rows of vented battens according to various embodiments.

FIGS. 25A-25E show a transition pan configured in accordance with other various embodiments.

FIGS. 26A-26B show schematics of PV module configurations to achieve an infinity visual effect.

FIGS. 27A-27D show PV module pan assemblies having PV modules and PV pans that can be provided with the systems as described herein according to various embodiments.

FIGS. 28A-28C show PV module pan assemblies having PV modules and PV pans that can be provided with the systems as described herein according to various embodiments.

FIGS. 29A-29D show PV module pan assemblies having PV modules and PV pans that can be provided with the systems as described herein according to various embodiments.

FIGS. 30A-30M show a roof system including PV module pan assemblies having PV modules and PV pans that can be provided with the systems as described herein according to various embodiments.

FIGS. 31A-31C show PV module pan assemblies having PV modules and PV pans that can be provided with the systems as described herein according to various embodiments.

FIGS. 32A-32D and 33 show edge treatments for adjacent PV modules that can be provided with the systems as described herein according to various embodiments.

DETAILED DESCRIPTION

The present disclosure describes various embodiments of photovoltaic roofing systems and associated systems and methods. Some embodiments relate to building integrated photovoltaic module assemblies and associated systems and methods. In various embodiments, the systems described herein lower costs of conventional systems in which a PV system is installed over a roof, and at the same time can provide an improved aesthetic for a PV roof system.

Certain details are set forth in the following description and in the Figures to provide a thorough understanding of various embodiments of the present technology. Other details describing well-known structures and systems often associated with PV systems, roofs, etc., however, are not set forth below to avoid unnecessarily obscuring the description of the various embodiments of the present technology.

Many of the details, dimensions, angles and other features shown in the Figures are merely illustrative of particular embodiments. Accordingly, other embodiments can include other details, dimensions, angles and features without departing from the spirit or scope of the present invention. Various embodiments of the present technology can also include structures other than those shown in the Figures and are expressly not limited to the structures shown in the Figures. Moreover, the various elements and features shown in the Figures may not be drawn to scale. In the Figures, identical reference numbers identify identical or at least generally similar elements.

As used herein, the term “substantially” refers to the complete or nearly complete extent or degree of an action, characteristic, property, state, structure, item, or result. For example, an object that is “substantially” uniform in height to another object would mean that the objects are either completely or nearly completely uniform in height. The exact allowable degree of deviation from absolute completeness may in some cases depend on the specific context, however, generally speaking, the nearness of completion will be so as to have the same overall result as if absolute and total completion were obtained.

As used herein, the term “about” is used to provide flexibility to a numerical range endpoint by providing that a given value may be “above” or “below” the value. For example, the given value modified by about may be, for example, by ±5%, ±10%, ±15%, ±20%.

Wherever used throughout the disclosure and claims, the term “generally” has the meaning of “approximately” or “closely” or “within the vicinity or range of”. The term “generally” as used herein is not intended as a vague or imprecise expansion on the term it is selected to modify, but rather as a clarification and potential stop gap directed at those who wish to otherwise practice the appended claims, but seek to avoid them by insignificant, or immaterial or small variations. All such insignificant, or immaterial or small variations should be covered as part of the appended claims by use of the term “generally”.

As used herein, the term “building integrated photovoltaic system” of “BIPV” generally refers to photovoltaic systems integrated with building materials to form at least a portion of a building envelope. For example, the BIPV system can form the roof or roofing membrane of a building. The BIPV systems described herein can be retrofitted, can be a part of a new construction roof, or a combination of both. The PV modules, PV module pans, or both (depending on the particular embodiment) can be used as the actual building envelope (e.g., roofing membrane) to provide a watertight or substantially watertight seal. Alternatively, in other embodiments, the PV components (e.g., photovoltaic modules and associated wiring) of the system may be affixed over the building envelope in a manner that simulates the appearance of BIPV without having the PV system components be part of the building envelope. In other words, the PV modules may be installed over a metal roof pan or support pan that makes up part of the building envelope. As used herein, the term “BIPV system” may be used to refer to either configuration.

As used herein, the terms “up-roof” and “down-roof” are used to provide orientation, direction, position, or a reference point relative to or in context of a roof or roofing surface upon which the systems described herein are installed on and/or form a portion of. Up-roof generally refers to an orientation that is relatively closer to the roof ridge while down-roof refers to an orientation that is relatively closer to the roof eave.

As used herein, the singular forms “a”, “an”, and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “includes” and/or “including”, when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

Spatially relative terms, such as “beneath”, “below”, “lower”, “above”, “upper”, and the like, may be used herein for ease of description to describe one element or feature's relationship to another element(s) or feature(s) as shown in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as “below” or “beneath” other elements or features would then be oriented “above” the other elements or features. Thus, term such as “below” can encompass both an orientation of above and below, depending on the context of its use. The device may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein are interpreted accordingly.

Although the terms “first”, “second”, etc. may be used herein to describe various elements, components, regions, layers and/or sections, it should be understood that they should not be limited by these terms. These terms are used only to distinguish one element, component, region, layer, or section from another region, layer, or section. Thus, a first element, component, region, layer, or section discussed below could be termed a second element, component, region, layer, or section without departing from the teachings of the present invention.

As used herein, the terms “and/or” and “at least one of” include any and all combinations of one or more of the associated listed items.

Rapid shutdown devices (“RSD”) for PV systems can be applied to the systems described herein, and can be located or positioned in various locations. In some embodiments, a recess or other opening can be made in structural support pans (e.g. a transition pan or a non-PV pan) through insulation such that RSD can be inset or positioned inside recessed opening. Vents can be positioned on top of opening to conceal or cover opening. Structural support pans can be elements of roofing frames or array systems that provide stability or integrity to the overall structures, as described in further detail below. RSD can be positioned within a box or other suitable container prior to positioning within recess. In other embodiments, RSD can be positioned under eaves, or eave flashings or gutters. In yet other embodiments, RSD can be positioned within attic portions of a building.

Generally, PV modules are crystalline-based solar panels, which can be either or both of monocrystalline solar panels or polycrystalline (multi-crystalline) solar panels. The laminate or wafer forming the solar energy-collecting surface of such PV modules can be mechanically coupled, adhered, or bonded to structurally supporting pans. In some embodiments, PV modules can include layers of amorphous silicon or thin film variations of solar energy-collecting laminates (unlike traditional thin-film solar materials directly applied to continuous metal sheets of a roof). Generally, PV pan-module assemblies as considered herein, including PV modules, solar panels and laminates, have individual structures that can be used in combination to form larger solar arrays and/or building structures, as set forth below. Alternatively, thin-film PV modules, such as cadmium telluride, copper indium gallium diselenide, or amorphous thin-film silicon may be used. In still further embodiments, cells based on perovskite or other as of yet non-commercialized materials may be used. The particular type of cell technology used is a design choice and not critical to the various embodiments of the invention.

FIG. 1A shows a prior art PV array installed on roof 100. The exemplary PV array of FIG. 1A includes six solar panels 101 or modules (identified individually as solar panels 101A-101F). Though not shown in detail, panels 101A-101F are mounted on roof 100 using one of various known rail-based or rail-free mounting systems, as are currently employed by solar installers, such as San Mateo, Calif.-based SolarCity Corporation.

FIG. 1B shows one type of conventional solar panel 101 in more detail. Solar panel 101 includes PV laminate 102, which in conventional silicon-based cells, consists of a silicon sandwich of p-doped and n-doped silicon layers, a top glass sheet protecting the laminate, and a back sheet that can include a plurality of layers—and rigid metal frame 103, supporting PV laminate 102. Although shown as a unitary structure, laminate 102 may include a plurality of individual solar cells that are wired together to form a single unit under the top glass sheet. In the example shown in FIG. 1B, frame 103 is a grooved frame with groove 104 surrounding the outer face of frame 103 on all sides. Grooved frame modules such as module 101 are manufactured and sold by SolarCity Corporation of San Mateo, Calif. In such a module, groove 104 serves as mechanism for attaching other mounting hardware (e.g., a leveling foot, an interlock) to join modules together and to support the modules over a roof surface. Those of ordinary skill in the art will appreciate that panel 101 may also have a plain, non-grooved frame. Non-grooved frames are typically interconnected to one another and connected to the roof using connectors that clamp down between the top and bottom edges of the frame.

Although these types of framed PV modules achieve their structural function, they are aesthetically suboptimal and have material usage inefficiencies. First, conventional PV systems, such as that shown in FIG. 1A, are typically installed over an existing roof, essentially requiring redundant structure since the PV array will shield most of the portion of the roof that it is installed over. Second, conventional systems are deemed by some people to be unaesthetic. Conventional PV modules usually come in one of two colors: blue, signifying a poly-crystalline silicon structure, and black, signifying a mono-crystalline silicon or thin-film structure. The metal frame portion can be painted black to help it blend in with the roof surface, or it can simply be raw aluminum. Regardless of whether blue or black modules are used, the difference between the look of the portion of the roof that is covered with solar and the remainder of the roof is generally quite dramatic. As a result, roofs that are partially covered with solar panels have an aesthetic contrast that can be seen from very far distances due to the difference in reflectivity, elevation, height, and/or color between these two very different surfaces.

Building Integrated Photovoltaic Array & Coupling Seams

FIG. 2A shows BIPV system 200 installed on a plane of roof surface 203. System 200 is arranged in vertical pans on existing roof 203 to mimic the look of an all metal standing seam metal (e.g., steel, aluminum, galvanized) roof with evenly spaced vertical seams running from the roof ridge to the eave. The resultant BIPV system is comprised of six vertical pan sections containing PV modules 201A-201R, regular roof pans 210, and dummy or transition pans 205 that complete the six vertical columns (e.g., col. 1=201A, 201G, 201M; col. 2=201B, 201H, 201N; col. 3=201C, 201I, 201O; col. 4=201D, 201J, 201P; col. 5=201E, 201K, 201Q; and col. 6=201F, 201L, 201R). As discussed in greater detail herein, in some embodiments, the PV modules in each column (e.g., 1, 2, 3, 4, 5, and 6) may be affixed to a roof pan containing raised seams on either side. In other embodiments, the PV modules in each column may make up a portion of the roof-facing portion of the pan. Ridge cap 215 sits at the top of the resultant array, and as discussed herein may be used for venting, heat dissipation, and wire management. Together, these elements form an integrated PV roofing system 200 that reduces the redundancy inherent in conventional PV systems while providing a uniform look.

Standing seam as understood herein refers to the raised seams running up-roof to down-roof on both sides of a roof pan that are used to interlocking adjacent pans. The standing seams can be vertically or upwardly extending sidewalls or flanges and may be held together with clips or other fasteners. The seams between pans may be covered with a cap or other feature that keeps them watertight while concealing the seam. While shown as extending substantially perpendicular to a base planar surface portion (e.g., the plane of the roof surface or PV modules), in other embodiments, the standing seams can extend at angles other than ninety degree. Systems and features described herein can also be applied to non-metal (e.g., comp shingle, tile) roofs.

The seams (e.g., raised seams) of adjacent roof pans used in the PV systems described herein can be interlocked (e.g., coupled or secured together) in a variety of manners. For example, seams can be interlocked by folding (e.g., bending, rolling) one seam over the another seam and crimping them together (see e.g., FIG. 3C), which creates equally spaced, interlocked seams running from roof ridge 209 to roof eave 213. In some embodiments, seams are interlocked or snap-locked by clips, clamps, covers, or other suitable mechanical fasteners (e.g., rivets and screws) that fit over the entire seam as described in more detail below with reference to FIGS. 4A-4D. In yet further embodiments, seams can be welded or otherwise bonded or adhered together. As noted above, in certain embodiments seams of systems described herein can be inverted (e.g., extended or bent in a downward direction such that they are positioned below the roof or PV module surfaces) as compared to the standing or raised seams.

In yet further embodiments, the seams can be hemmed, folded, or bent into different configurations to provide improved engagement features as described in more detail below (see e.g., FIG. 4B). For example, a clip used to engage and couple the hemmed seams can include one or more hook portions that can engage (e.g., be “snap-locked”) the seams in a manner to provide increased resistance to pullout in response to uplift forces (e.g., wind uplift). Further, having such hemmed or bent seams can provide improved safety when shipping and installing such components by reducing the number of exposed sharp edges. In yet other embodiments, the seams can be inverted or extended (e.g., bent) downward such that ends of the seams are positioned below the planar, roof surface portions of the metal roof

System 200 includes a solar array of eighteen low profile building integrated PV modules 201 (identified individually as PV modules 201A-201R arranged in six columns and three rows of PV modules). PV modules 201 can, in some contexts, also be referred to as PV panels or solar panels. In other embodiments, system 200 can include a different number of columns or rows of PV modules (e.g., two rows). Further, the columns and/or rows can be spaced apart as desired (e.g., not directly adjacent to each other). System 200 can also include dummy modules 205 (alternatively referred to as dummy panels) and columns of standard roof pans 210 that contain no solar PV modules. Dummy modules 205 generally refer to roof structures that can mimic the appearance of PV modules 201, serving a function similar to standard roof pans 210. In some contexts, roof pans 210 can alternatively be referred to as general support pans or non-PV pans.

As discussed above, PV modules 201A-201R can be placed or mounted within ordinary pans that are substantially the same as non-PV pans 210. Alternatively, they may be installed in, or part of special pans (e.g., pans 220 in FIG. 3A) so that the height of modules 201A-R is substantially equal to the height of non-PV pans 210. Moreover, as discussed in greater detail herein, the pans holding modules 201A-201R, in columns 1-6, may be specifically configured with additional recesses (e.g., 224) to accommodate module junction boxes 217 and route power cables as shown in FIGS. 3A and 3C. In contrast, standard roof pans 210 generally refer to traditional structures and panels used for the tiling or construction of roofs, which do not include PV electricity generation components. Such non-PV pans 210 may be installed over roof battens 211 as seen in the partial cutaway view of FIG. 3A. Alternatively, they may be installed directly on the roof deck. Dummy modules 205 are roof pans that are used to complete a column of PV pans, after the PV portion stops. Dummy modules 205 may not only mimic the appearance of PV modules 201, but they may be mounted on PV pans 220 instead of PV module 201. In such a case, dummy modules 205 can maintain a uniform appearance alongside PV modules and provide space beneath the generally uniform planar surface of PV modules 201 of system 200, in which electrical components can be centralized, ventilation can be achieved, or where access to underlying roof 203 (e.g. sub-roofing, an attic, etc.) can be provided.

Dummy modules 205 can be substituted for, or configured to appear similar to, roof pans 210 and/or PV modules 201. For example, dummy modules 205 can be painted to match in color or appearance of roof pans 210 and/or PV modules 201. In some embodiments, dummy modules 205 can be used as transition pans at up-roof (e.g. at ridge 209 of roof 203) or down-roof portions (e.g., at eave 213 of roof 203) at the beginning and/or end of a column of PV modules 201, as described in more detail below. In other embodiments, roof pans 210 can be used as transition pans, such as part of a column of PV modules 201. As used herein, the term transition pan refers to sections of roof pan that are used to transition between different pan types (e.g., PV pan 220 and non-PV pan 210) or to complete a column before PV modules start or after they stop. In certain embodiments, dummy modules 205 can be installed adjacent to side portions of roof 203, in place of, or along with roof pans 210. In other embodiments, roof pans 210 can be used or substituted for one or more dummy modules 205. In some embodiments, dummy modules 205 can include roof pan 210 or panel or a PV module layer (e.g., glass, backsheet, etc.) positioned on a batten or other pan mount.

System 200 can include ridge cap 215 to cover roof ridge 209 and may be used to conceal and protect wires (e.g., conduits or cables) or other equipment (e.g., fans, vents, connectors, inverters, jumpers, home-run connections). System 200 can also include other roofing components (e.g., flashings, gutters, vents, caps, covers, trims), for example, at eave 213, or at hips, valleys, or sides of the roof (not shown). While FIG. 2A shows system 200 including eighteen PV modules 201A-201R, in some embodiments, system 200 includes a solar array with more or less than eighteen PV modules 201. Further, in some embodiments, a column of roof pans 210 can also include dummy modules 205 and/or PV modules 201.

FIG. 2B shows exemplary low-profile BIPV module 20. In various embodiments, PV modules 201 can include any number of cells, including more or less than conventional 60-cell or 72-cell solar panels. For example, PV module 201 may have 3 columns of 11 cells, 3 columns of 10 cells, or, in a shingled configuration, 3 columns of thirty-three 33 sub-cells, where each cell is cut into 3 shingled cells. PV modules 201 can also include bi-facial, shingled cells, or a combination thereof. As shown, PV modules 201 can be about half the width of conventional, full-width modules. Further embodiments of PV modules 201 can have a specific number of solar cells, such as 12-cell, 20-cell, 24-cell, 30-cell, 36-cell, 40-cell, 42-cell, 48-cell, 54-cell, or 56-cell embodiments. Other embodiments of the present technology can include PV modules having 60-cell, 70-cell, 80-cell, or 92-cell solar panels, or other such solar panels as known in the field. Further embodiments can have PV modules 201 with other number-of-cell embodiments within the above-considered ranges. The various embodiments of PV modules 201 with different numbers of solar cells allows for flexibility in selecting solar panels appropriate for any given system installation.

PV modules 201 can also be frameless or have a minimized frame structure, as shown in FIG. 2B. In other words, PV modules 201 can be constructed without a rigid frame (e.g., made of metal, plastic) surrounding or enclosing the edges of the panel, or in some embodiments, surrounding only a portion of the bottom and sides but not the top of the module. Individual PV modules 201 can include layer of top glass 208 and a back sheet that will sandwich the internal PV layers as described in more detail below with respect to FIGS. 2C and 2D without any framing. In certain embodiments, because PV modules 201A-201R can be supported by PV pans 220 (e.g., tray, plate—as shown, for example in FIG. 3A), where PV pans 220 with raised portions 222, whereas PV pans 220 sit on and/or are secured to roof 203 or other suitable roof surface at valleys 224, PV modules 201A-201R may not need to be as strong as framed panels in an ordinary or conventional array. In other words, in an ordinary or conventional array, the panel frame can become part of the mounting system and is subject to the same forces and moments as the mounting system, whereas in contrast, PV pans 220 can primarily bear load instead of PV modules 201. PV modules 201 and PV pans 220 form PV module-pan assemblies when bonded or otherwise coupled to each other. Frameless, low profile solar PV modules are not required. For example, a framed module can used and the frame can be color matched to PV pan 220.

Generally, in various embodiments, either or both of non-PV metal roof pans and transition pans can be painted to appear like PV modules, for example, replicating solar cell lines, color, and other visual characteristics of PV modules. Similarly, either or both of non-PV metal roof pans and transition pans can have visual or structural characteristics to track PV module-pan assemblies. The combination of these elements can provide for an overall roof appearance that is visually pleasing, with minimal points of contrast or sharp edges to distract the eye of an observer.

It should be understood that in these embodiments, roof pitches where such systems are installed are non-zero, and that the systems are installed to account for the angle or slope of (non-flat) roofs. The distances or gaps between various pans, modules, and assemblies, and the degree to which such gaps are concealed will be dependent on roof pitch, the distance a viewer is from the roof, and the height of the viewer.

FIGS. 2C and 2D show in further detail the layers of exemplary PV modules 201. In some embodiments, PV modules 201 described herein refer to crystalline-type (e.g., non-thin film or amorphous solar) solar modules. However, PV modules 201 are not limited to crystalline-type solar cell technology. For example, in other embodiments, thin-film or amorphous solar (e.g., amorphous silicon) can be used as laminate layers with certain embodiments of PV modules 201 described herein. In yet further embodiments, hybrid crystalline and amorphous solar modules can be used with PV modules 201 systems described herein. In other embodiments, other types of solar cells (e.g., non-silicon based semiconductors, partial silicon, non-crystalline, partial crystalline, organic, carbon-based, perovskite, cadmium-telluride, copper-indium-gallium-selenide (“CIGS”), dye sensitized, transparent luminescent solar concentrator, polymer, transparent cells) can be provided as part of PV modules 201.

As shown in FIG. 2C and noted above, in some embodiments, PV module 201 can include PV layers 202 (e.g., solar cells, semiconductor layers, bussing, insulation, laminate) sandwiched between encapsulation layers 204 (e.g., EVA). PV modules 201 can further include one or more backsheets 206 (e.g., polyvinyl fluoride film) and/or glass layers 208. As shown in FIG. 2D, PV modules 201 can include first and second glass layers 208 (e.g., “glass on glass”) sandwiching encapsulation layers 204. The glass on glass PV modules 201 can also eliminate or reduce the need for additional intermediate material layers (e.g., a pan portion, underlayment, felt paper) between a bottom of PV module 201 and existing roofing surfaces, which may otherwise be used for fire protection or other purposes. In certain embodiments, PV modules 201 can include both glass layer 208 and one or more backsheet layers 206. In yet further embodiments, PV modules 201 can include one or more additional layers (e.g., transparent coatings, insulation layers, phase change material layers to help with heat transfer) on a top side (e.g. the side of PV module 201 incident to solar energy), rear side (e.g. the side of PV module 201 proximate to the installation surface or roof), or as intermediate layers.

In some embodiments, tape, edge trim, or other edge protection materials can be applied to corners, edges or sides of PV modules 201 to protect PV modules 201 from damage during shipping or installation. These can be configured to be tear-away or permanent materials. Encapsulation layers 204 or backsheet layers 206 can also be optionally trimmed during manufacturing such that they can be rolled over PV module 201 edges and laminates to provide edge protection. Any or all portions of encapsulation layers 204 or backsheet layers 206 can then be removed prior to, or during installation, on a roof. In certain embodiments, glass edges of glass layer(s) 208 can be rounded or beveled accordingly for ease of installation.

Although backsheet layers 206 can have a light color, such as white, PV modules 201 can include non-white (e.g., black, blue, transparent) backsheet layers 206. Non-white backsheet layers 206 can improve aesthetics by reducing glare or reflection off or through glass layers 208 or a mounting pan as compared to white backsheet layers 206. Additionally, black or blue backsheets tend to be closer in color to conventional solar cells or PV modules. Thus, non-white backsheets can create a more uniform appearance with the rest of the system. Backsheet layers 206 (or other layers) may be cut at an angle, such that the cut, exposed portion of backsheet layer 206 faces roof 203, or is oriented in a substantially downward direction (e.g., toward the roof) when PV modules 201 are assembled and mounted to the roofing surface.

The arrangement of backsheet layers 206 above or below PV layers 202 and encapsulation layers 204 can provide for added thermal control and/or directed light reflection within PV modules 201. In some embodiments, PV modules 201 may include first and second backsheet layers 206 (e.g., non-white or white) sandwiching encapsulation layers 204 (e.g., on both air and cell sides of PV module stack). Further, backsheet layers 206 can be integrated with encapsulation layers 204 or adhesive layers in certain embodiments. Certain backsheets can also provide PV modules 201 with improved thermal dissipation or heat reflective properties, electrical insulation, or protection from damage, moisture, or UV degradation. Such backsheets can include dyMat™, DuraShield®, or PowerShield®.

FIG. 3A shows a partial cutaway view of a portion of building integrated PV system 200, and FIG. 3B shows a cross-sectional view of the same system 200. FIGS. 3A and 3B show the layers of different materials or components used to construct system 200. System 200 can be installed, for example, directly over an existing composition shingle roof layer and/or other suitable roof surface or structure (e.g., a roof deck, metal seam roof, insulating layer, underlayment, ice dam protection membrane, slip sheet, batten, purlin, rafter, flashing, furring strip). Alternatively, the existing roof may be scraped clean before installing system 200. In still further embodiments, system 200 may be installed as part of new construction where there is no existing weather resistant roof surface other than the plywood roof deck.

After a desired size of the solar array has been determined (e.g., based on orientation of the roof, space considerations, weight considerations, amount of electricity production required, efficiency of modules, amount of sunlight), trim, vent, or flashing at the eave or sides of roof 203 can be installed. Battens 211 can then be installed across roof 203 in areas (e.g., columns) of roof 203 where non-PV modules will be placed. For a composition shingle roof, battens 211 can be attached directly over the composition shingle roof in a series of rows that run from roof ridge 209 down to roof eave 213 and/or as continuous or semi-continuous layers or sheets of insulation material, which in some aspects, can be referred to as intermediate layers 219 of roof 203. Non-PV roof pan(s) 210 and/or dummy modules 205 can then, for example, be installed over battens 211.

In alternative embodiments, battens 211 can be pre-installed, secured to, or otherwise integrated with an underside of non-PV roof pans 210 and/or dummy modules 205 (e.g., forming a structurally integrated roof panel) prior to securing roof pans 210 to roof 203. For example, as shown in FIG. 3B, non-PV roof pans 210 can include batten 211 (e.g., foam, isoboard, polyisocyanurate foam, or other insulation materials) sandwiched between upper pan surface 210A and lower pan surface 210B. Lower pan surface 210B can be secured to upper pan surface 210A to provide improved overall rigidity of roof pan 210. This can help reduce unintended detachment of roof pans 210 as well as resistance to uplift from wind. For example, lower pan surface 210B can include raised seams 232 secured or configured to be secured to standing seams 212 of upper pan surface 210A with seam clips or other suitable fasteners (e.g., rivets), or be welded together. Further, in certain embodiments, batten material can include one or more primary wiring channels 226 (or “pathways”) that provide space for wire routing and management, and that can be oriented in either or both of an “East-West” direction (transverse to the length of roof pan 210) or a “North-South” direction (longitudinally along the length of roof pan 210). Similarly, in some embodiments, lower pan surface 210B can include one or more secondary wiring channels 228 that provide space for wire routing and management, and that can be oriented in either or both of an “east-west” direction (transverse to the length of roof pan 210) or a “North-South” direction (longitudinally along the length of roof pan 210).

While battens 211 are shown in FIG. 3A as extending generally horizontally (e.g., side-to-side) in rows across roof 203 between corresponding seams 212 (identified individually as seams 212A and 212B) of non-PV pans 210, battens 211 can be positioned on or extend across roof 203 in a direction generally parallel to or at an angle to a longitudinal axis of standing seams 212. Although battens 211 have a rectangular cross-section, any other suitable cross-sectional shapes (e.g., triangular, square, trapezoidal) can be used. Battens 211 can have one or more cross-sectional sizes. For example, battens 211 can have a cross-sectional dimension equal to or about 1″×4″, 1.5″×4″, 1.75″×4″, 2″×4″, 3″×4″ (where quotation marks indicate inches), or any value in between.

Battens 211 may also be spaced apart or include one or more channels or apertures such that cables, conduits, or other wires can be routed through or pass across the roof underneath the pans (e.g., in either or both of North-South and East-West directions). Battens 211 can, for example, be made of wood or other suitable materials (e.g., foam, rubber, polystyrene, isoboard, metal, polyisocyanurate foam). In certain embodiments, battens 211 can include a layer of reflective material. In yet further embodiments, battens 211 can include one or more continuous or semi-continuous layers of suitable materials as set forth above.

Non-PV roof pans 210 can be manufactured in pre-cut lengths (e.g., 6′, 8′, 10′) and cut to fit into custom lengths as needed for any given installation. Roof pan 210 can also be pre-formed with standing seam 212, ridge or other feature that matches or mimics PV pan standing seam 214 as configured between adjacent low profile building integrated PV modules 201. As shown in FIG. 3C, roof pan 210 can have standing seam 212 with larger outer seam 212A on the left side and smaller inner seam 212B on the right side. PV standing seams 214, also with left side larger outer seam 214A and right side smaller inner seam 214B, can mirror seams 212A and 212B, or vice versa. These configurations facilitate interconnection or interlocking of standing seams 212 of roof pan 210 with corresponding standing seams 214 of PV pan 220, forming interlocked standing seam 230. Alternatively, all seams can be the same. Battens 211 can be sized to maintain roof pan 210 at a height or elevation that is equal to or substantially similar to surrounding PV modules 201 and dummy modules 205. Battens 211 can also support roof pan 210 from below so that if for example, an installer steps on roof pan 210 during installation, roof pan 210 is less likely to dent or take on the shape of the course of shingles below.

FIGS. 3A and 3C show one or more PV pans 220 that extend in a column adjacent to roof pan 210. PV pans 220 in this embodiment are partially corrugated pans with a series of ridges 222 (alternatively referred to as peaks) and channels 224 (alternatively referred to as troughs or valleys) formed in PV pans 220 that provide support to PV modules 201 mounted on PV pan 220. PV modules 201 and dummy modules 205 can be installed over PV pan 220 to form a complete column of similar looking material. Dummy modules 205 can also be made of glass, painted metal, plastic or other material that matches the color, reflectivity, and/or texture of PV modules 201 or non-PV roof pans 210.

As noted above, dummy modules 205 can also be configured as transition pans at down-roof or up-roof portions of a column of PV modules 210 and PV pans 220. Transition pans can be installed at up-roof and down-roof portions (e.g., ridge or eave, respectively) of a PV system (e.g., a roof). Dummy pans 205 can appear the same or substantially similar in appearance to the non-PV roof pans 210 and/or the assembly of PV modules 201 with PV pans 220. Various embodiments are described in more detail and shown below.

Similarly, non-roof pans 210 can also be similarly configured (e.g., painted) to match the color, reflectivity and texture of PV modules 201, or vice versa. In some embodiments, modification of dummy modules 205 or non-PV roof pans 210 can include grid-lines or other features (e.g., printed cells, bussing, or busbars) to further match the appearance of PV modules 201.

In certain embodiments, one or more PV module junction boxes 217 (alternatively referred to as “j-boxes”) can fit within or extend into one of channels 224 of PV pan 220. Junction boxes 217 can be attached to or extend from a bottom surface of the PV modules into channels 224. As described in more detail below, having more than one junction box 217 (e.g., V+ and V−) can provide additional or improved potential wire routing pathways or connections. Further, including more than one junction box 217 can decrease the profile or size required of each junction box 217, relative to a single j-box implementation and also reduce the amount of external or internal wire (e.g., copper wire) required for electrically connecting cells and PV modules of a PV system relative to using one junction box 217 in certain embodiments. In certain embodiments, efficiency can be improved by reducing internal or external resistances by reducing the amount of internal or external wiring.

One or more junction boxes 217 can be center mounted, for example, on the underside of PV module 201, as shown in the center portion of FIG. 3C. Junction boxes 217 can also be mounted off-center (e.g., more proximate to opposing sides and/or ends of PV module 201 rather than a center or center-line of PV module 201) on the underside of PV module 201, as shown under PV module 201 in the right side portion of FIG. 3C. In some implementations, primary wiring channels 226 and/or secondary wiring channels 228 can accommodate the wires and connectors that interconnect adjacent or proximate PV modules 201 to each other as part of system 200, as well as the home run connection to a power substation connected to system 200. Junction boxes 217 can be pre-assembled, clipped, or bonded to PV modules 201. Wires or cables for connection to other junction boxes 217 can optionally be pre-attached (e.g., taped, with clips) to PV modules 201 prior to installation. In certain embodiments, PV modules 201 can include micro-inverters, DC optimizers, or other module-level electronics as part of or separate from the housing that also holds junction boxes 217.

As shown in FIG. 3C, either battens 211 or PV pans 220, or both can be installed over existing composition shingle roof or roof deck 203. In some embodiments, intermediate layers 219 of felt paper, insulation (e.g., battens, isoboard, polyisocyanurate foam, foam), reflective layers, underlayment (e.g., moisture, fire protection, or other suitable insulation layers such as VersaShield®, MetShield®, or DensDeck®), and/or other suitable layers can be positioned between shingle roof 203 and bottom of battens 211 or PV pans 220. In certain embodiments, battens 211 or PV pans 220 can be mounted onto an existing or newly installed roof deck with no composition shingle thereon. In yet further embodiments, intermediate layers 219 can be positioned on top of battens 211 or further insulation layers, instead of, or in addition to, under battens 211. Further, battens 211 (e.g., insulation layer or other spacers or raisers) can space roof pans 210 to a desired height above roof 203 surface, for example, such that roof pans 210 are coplanar with PV modules 201 or dummy modules 205.

Installation of system 200 can continue with another PV pan 220 or column of PV pans 220 being joined to first column of PV pan(s) 220 via another respective standing seam 230. In certain embodiments, PV pans 220 will be covered by PV modules 201, roof pans 210, or dummy modules 205, thus, screws or other suitable fasteners (e.g., glue, nails, clips) can be used to attach further PV pans 220 directly to roof 203 surface or structure. Similarly, further columns of roof pans 210 and/or PV pans 220 can be installed on either side of system 200 not show, in other words, to the further right of side of PV pans 220 and/or to the further left of non-PV roof pans 210, and joined with respective roof pans 210 and PV pans 220 using another standing seam 230.

After non-PV roof pans 210 and PV pans 220 have been installed with standing seams 230 formed for the full coverage of system 200 for given roof 203, either dummy modules 205 and low profile PV modules 201 can be installed directly over PV pans 220. In some embodiments, PV modules 201 can be joined to PV pans 220 prior to installing PV pans 220 to roof 200 and/or forming interlocked seams 230. Dummy modules 205 can be bonded to roof pans 210 and PV modules 201 can be bonded to PV pans 220, for example, with a non-watertight (e.g. hook and loop) or watertight/substantially watertight adhesive (e.g., glue, sealants such as PV 804, RTV, PV-8030, thermal adhesive), or otherwise suitably coupled via one or more mechanical fasteners (e.g., clips, clamps, screws), depending whether system 200 is configured to allow water to flow between PV modules 201 and PV pans 220 or to maintain water above PV module 201 surface and out of PV pan 220. For example, in various embodiments, dummy modules 205, roof pan 210, or PV modules 201 can have one or more standing seams or rail portions that can be bonded to a separate pan that has seams or rails and can further be interlocked under a seam cover or other engagement features to form of standing seam 230. In other aspects, dummy modules 205 can be bonded to PV pans 220, to be arranged intermittently between with PV modules 201 also bonded to PV pans 220.

Once the array has been completed and all electrical interconnections made, ridge cap 215 can be installed over roof ridge 209 to conceal top edges of roof pans 210 and PV pans 220 as well as any PV wires or cables. The result of deploying and installing roof pans 210, dummy modules 205, and low profile building integrated PV modules 201 is to create an aesthetically consistent PV array with a uniform or substantially uniform look and elevation that is essentially a re-roof (or a newly installed roof) of an existing structure (e.g. a customer's home) with less material than conventional solar plus roofing. The entire roof, including PV modules 201, dummy modules 205, and flat roof pans 210 form a planar or substantially planar array of uniform or substantially uniform height. Because metal roofs are known to generally last 30-50 years, depending on climate, roof 203 can last at least as long as the solar panel system 200, thereby greatly minimizing or eliminating the possibility that roof 203 will expire before BIPV system 200 has reached an expected end of functional life. While shown here as part of an on-roof system, it can be understood that the installation process can also apply to PV pans and modules assembled as part of a built-in solar assembly, incorporated into the framing structure of a roof.

FIGS. 4A-4I show other ways to assemble and interlock the seams of adjacent pans and modules and/or attach a PV module to a pan (e.g., a corrugated pan). FIG. 4A is a general representation of standing seam assembly 400, and FIG. 4B is a magnified, cross-sectional view of a portion of a PV system having corresponding standing seams of two adjacent pans, non-PV pan 410 and PV pan 420, interlocked or coupled together with one or more seam clips 432 to form standing seam assembly 400 in accordance with various embodiments. This could be a system such as system 200 in FIGS. 2A, 3A-3C, or a system such as that shown in other embodiments of this disclosures. Non-PV pan seam 412 of non-PV pan 410 and PV pan seam 414 of PV pan 420 can be interlocked with seam clip 432 positioned therebetween. Seam clip 432 can include two or more tabs (identified individually as first tab 432C and second tab 432D) that can be folded (e.g., bent or crimped) over respective standing seams non-PV pan seam 412 and PV pan seam 414 to interlock non-PV pan 410 and PV pan 420 together. Moreover, standing seam assembly 400 can, for example, hold and position both non-PV pan 410 and PV pan 420 such that the surfaces of non-PV pan 410 and PV module 401 form a uniform or substantially uniform planar surface. In aggregate, PV module 401, whether bonded, adhered, or mechanically coupled to PV pan 420, can be referred to as a PV pan-module assembly.

In various embodiments, as noted above and shown in FIG. 4A, standing seams, such as non-PV pan seams 412 of non-PV pans 410 can be hemmed or bent into various shapes rather than extend in a substantially vertical direction. The various shapes of non-PV pan seams 412 and PV pan seams 414 can include, for example, standing seams that are hemmed inwardly or medially toward each other, closed hems (e.g. with no gap), open hems where the hemmed portion can extend at various angles relative to a vertical axis. Such hemming can provide improved stiffness and rigidity that can help mitigate wind uplift as well as ease of installing or moving pans. The tabs of seam clips 432 can then include bent, hook, J-shaped, other projection, or engagement portions 438 for engaging hemmed non-PV pan seams 412 (e.g., in a snap-lock manner). Tabs of seam clips 423 can be installed extending generally upward in a vertical direction and then bent along a path P in FIG. 4A to be in an orientation to latch or interlock with standing seams. Seam cover 436 can then be cut to the appropriate length and assembled over the top of the interlocked (bent-over) seam clips 432 and standing non-PV pan seams 412. As noted above, this secured assembly can provide improved resistance to pullout of pans from the clips in response to, for example, wind uplift. Similarly, PV pan seams 414 of PV pans 420 can be hemmed or bent into various shapes rather than extend in a substantially vertical direction, and the tabs of seam clips 432 can include bent, hook, J-shaped, other projection, or engagement portions 438 for engaging hemmed PV pan seams 412 to secure PV pans 420 to a structure.

Shown in FIG. 4B, seam clip 432 can be attached to an existing roof surface or structure 407 (e.g., roof deck, composition shingle, rafter) prior to laying the pans over seam clip 432. As shown, in some embodiments, seam clip 432 has an L-shaped cross section with base portion 432A that extends under a lower surface of one of the non-PV pan 410 or PV pan 420 when attached to roof surface 407, and wall portion 432B extending between the respective non-PV pan seam 412 and PV pan seam 414. Seam clip 432 can include first tab 432C and second tab 432D, each of which can be configured to bend in opposite directions from each other, and thereby be positioned to latch or couple with standing seams on either side of seam clip 432. Further, both first tab 432C and second tab 432D can include one or more projections or “wing” portions, referred to as first tab wing 432E and second tab wing 432F, respectively, to engage with corresponding engagement features of seam cover 436 as described in more detail below.

In certain embodiments, seam cover 436 (or cap) can be attached over adjacent non-PV pan seam 412 and PV pan seam 414. Seam cover 436 can help reduce and ideally prevent the ingress of water, wind, or other debris to the space under either non-PV pans 410 or PV pans 420, or between standing seams. In various embodiments, seam cover 436 can include engagement features 438 (e.g., hooks, curved portions, J-shaped end portions) to engage or mate with corresponding projections, such as first tab wing 432E and second tab wing 432F, extending from first tab 432C and second tab 432D, respectively, to secure or couple seam cover 436 to seams clips 432 onto the respective standing seams of interlocked pans. In some aspects, first tab wing 432E and second tab wing 432F can have a spring tension, such that engagement between first tab wing 432E and second tab wing 432F with engagement features 438 secures seam cover 436 with seam clip 432 due to the mechanical interlocking of these parts and/or the frictional interface between these parts due to the restoring spring force of first tab wing 432E and second tab wing 432F on opposing interior sides of seam cover 436.

As shown, PV modules 401 can be attached to the upper surfaces (e.g., ridges 422) of corrugated PV pans 420 with adhesive 440 (e.g., hook and loop, sealant, glue) or with other types of suitable mechanical fasteners. Adhesive 440 can include one or more hook and loop strips or patches. In other embodiments, glue or other types of adhesives 440 can be applied to PV module 401 and PV pan 420 to couple or bond PV module 401 to PV pan 420. In some embodiments, the underside or backside (e.g., backsheet) of PV module 401 can include one or more layers, strips, and/or patches of padding 442 between applied adhesive 440 and PV module 401. Padding 442 can help protect PV module 401 and/or improve adhesion with adhesive 440. In other embodiments, padding 442 can be attached to the ridge portions 422 of pan 420. In certain embodiments, padding 442 (e.g., VHB tape, hook and loop) of a desired thickness can be applied to PV pans 420 or PV modules 401 in order to set PV modules 401 at a desired height above PV pan 420, such that PV module 401 will be mounted at a specified height (e.g. uniform with proximate non-PV pans 410) after applying adhesive 440. In such cases, padding 442 can be mounted to PV modules 401 prior to the application of adhesive 440.

FIGS. 4C and 4D are cross-sectional views of building integrated PV system 400 with seams secured according to other embodiments of the present technology. As shown, respective non-PV pan seams 412 of roof pans 410 and PV pan seams 414 of PV pans 420 can be secured together or interlocked by overlapping the seams and using rivets 416 to secure them together. As described above, PV pans 420 can be secured to the roof through the overlapping portion of via one or more rivets 416, screws 418, or other fastening members 444 (where fastening members 444 can be nails, bolts, etc.). FIG. 4D shows an embodiment where corresponding non-PV pan seams 412 of adjacent columns of non-PV pans 410 (e.g. roof pans) are secured together with rivets 416. Further, screws 418 can be hidden under an upper seam of the overlapping non-PV pan seams 412 and extend through the lower seam into an underlying roof (e.g., into a batten, rafter, deck, or other roof structure) to secure non-PV pans 410 to the underlying roof.

FIGS. 4E-4G show various isolated views of an embodiment of seam clip 432 that can be used to interlock or couple standing seams of PV pan-module assemblies, transition pans, or roof pans. Seam clip 432 can be configured to have tab portions, hook portions, or the like. Seam clip 432 can have a substantially L-shaped configuration or body having first surface 432A (alternatively referred to as a “base” surface) and second surface 432B (alternatively referred to as a “wall” surface) extending substantially perpendicular relative to each other. Such seam clips 432 can save or reduce manufacturing costs (e.g., by having one SKU). Seam clip 432 can be dimensioned such that seam clip 432 can be positioned below battens or other insulation layers (e.g., isoboard) to couple seams of adjacent pans (e.g. roof pans, PV pans, non-PV pans, transition pans, etc.) in a first configuration. Seam clip 432 can also be positioned above battens or other insulation layer to couple seams of adjacent pans in a second configuration.

In some embodiments, first surface 432A is smaller than second surface 432B (e.g., FIG. 4E). In other embodiments, first surface 432A can have a greater length relative to second surface 432B (e.g., FIG. 4G). Each of first surface 432A and second surface 432B can include corresponding tab portions that can be bent over as noted above. In the context of the present disclosure, first surface 432A can be considered the portion of seam clip 432 that is in contact with the mounting surface while second surface 432B can be considered the portion of seam clip extending upward and perpendicularly away from the mounting surface. Thus, if seam clip 432 is reoriented for a particular installation, the base surface and wall surface of seam clip can be defined such that second surface 432B can have a greater length relative to first surface 432A. Accordingly, both first tab 432C and second tab 432D refer to bendable tabs at the end of second surface 432B, although both first surface 432A and second surface 432B have tabs at their ends. The particular tabs used will depend on the orientation of clip 432. As a result, instead of having two SKUs for two different sized seam clips 432, one SKU or seam clip 432 can be provided that can be mounted in two different configurations.

FIGS. 4H and 4I show gaps between opposing side edges of PV module 401 and standing seams, particularly PV pan seam 414 in an exemplary PV roof system according to various embodiments. As shown, in order to improve aesthetics (e.g., color matching) and to reduce debris (e.g., dirt, water, ice) from being lodged between PV modules 401 and standing seams, the gaps G between the two structures can be taped (with a colored tape) or painted accordingly. In some embodiments, sealant (e.g. a silicon-based sealant) can be used to fill the gap. In other embodiments, sealing member 450 (e.g., made of rubber or other suitable materials) can also be inserted and secured within gap G or seam. Sealing member 450 or tape or adhesive in the side gaps G can also improve adhesion or strength of the bond between PV module 401 and PV pan 420, as such elements add further locations where PV module 401 is bonded to PV pan 420 in addition to adhesive under PV module 401. In other embodiments, sealing member 450 can be positioned between PV module 401 and a rail physically connected to underside of PV module 401.

As discussed in greater detail herein, in other embodiments, vertical seams 414 may be attached to either side of PV modules 401 so as create an integrated pan and module, thereby eliminating the need for a separate PV module pan. In such cases, the PV module is actually part of the building envelope. This distinction is significant because in such embodiments, wiring may only reside under the PV modules and therefore, within the building envelope, triggering different code requirements related to wire management.

FIGS. 5-8 and 9A-9B are perspective views and schematic cross sectional or front views of a portion of BIPV system according to other various embodiments. In the embodiments shown in these figures, PV modules 501 and PV module pan 520 are integrated into a single structure, thereby simplifying the installation process. As shown, a bottom surface (e.g., backsheet) of PV module 501 is bonded (e.g., adhered, secured, coupled) to pan 520 (e.g., sheet metal). In such embodiments, pan 520 extends across the entire or substantially the entire bottom surface of PV module 501, forming PV module-pan assembly 560 (e.g., a bonded PV module and pan). Thus, PV module-pan assembly 560 forms a portion of a new roofing membrane (e.g., maintaining the area between the pan and module dry) above an existing roof or roof surface. Pan 520 includes standing seams that can be interlocked (e.g., with seam clips and a seam cover) to seams of adjacent pans as described above. In other embodiments, pan 520 can include inverted seams as noted above with respect to other embodiments.

In various embodiments, pan 520 is coupled to spacer or support 562 that is attached to the roof surface or other roof structure. In some embodiments, pan 520 can be coupled to PV module 501 prior to installation to a roof surface. Support 562 can be made of foam or other suitable materials (e.g., polystyrene, polyisocyanurate foam) and can elevate PV module 501 and pan 520, referred to in combination as PV module-pan assembly 560, above the existing roof surface (e.g., to provide channels for airflow or j-box(es) as described in more detail below). As described above, adjacent columns of non-PV roof pans can sit on battens or other spacers (e.g., insulation layers) to maintain a planar or uniform height of the plurality of pans and PV modules forming the building integrated PV system.

In certain embodiments, support 562 can include one or more channels 564 passing underneath and open to a bottom surface of pan 520. Channels 564 can provide space to accommodate junction box 517 attached to the bottom of PV module-pan assembly 560 as well as space for associated wires. Also, channels 564 can provide space for airflow underneath PV module-pan assembly 560. Further, openings 566 (e.g., a window, cut-out) can be formed in pans 560 to allow junction box 517 to extend down into one of channels 564 when PV module-pan assembly 560 is coupled to support 562. In certain embodiments, rows of channels 564 or other cut-outs (e.g., perforations) can be made through support 562 to allow wires to be run in a direction generally transverse (e.g., side to side) to a longitudinal axis of pan 560.

At one end, for example, first edge portion 568, of pan 520 may extend past PV module 501 to allow room for two successive assemblies 560 to overlap within a column. Thus, first edge portion 568 of a top surface of pan 520 can be exposed. Second edge portion 569 (e.g., an overhang, ledge) of PV module-pan assembly 560, on the opposing side of PV module-pan assembly 560 from first edge portion 568, can extend in an opposite direction from first edge portion 568 past a portion (e.g., top or bottom edge portion) of support 562 when PV module-pan assembly 560 is coupled to support 562. This arrangement can allow for a portion of first PV module-pan assembly 560A to lay or be positioned on a region of second PV module-pan assembly 560B within a column of PV module-pan assemblies. For example, as shown in FIG. 7, second edge portion 569A of first PV module-pan assembly 560A overlaps and sits on top of exposed portion 568B, a top surface of second PV module-pan assembly 560B. This will tend to direct rain water down the array rather than under the array.

In systems as shown with pan-to-pan contact (e.g., a bottom pan surface portion of first PV module-pan assembly 560A to a top pan surface portion of second PV module-pan assembly 560B), gap 572 can be present between PV modules 502 and/or supports 562 at these overlapped portions. In some embodiments, gap 572 extends between the bottom edge and top edge of first PV module-pan assembly 560A and second PV module-pan assembly 560B, or PV module 501 edges. In other embodiments, portions of PV module 501 edges of first PV module-pan assembly 560A and second PV module-pan assembly 560B can abut each other when installed. In yet further embodiments, gap 1972 can be filled or covered (e.g., reduced) with a sealant or with the use of edge trims or other sealing members (e.g., gaskets, edge protect, tape) as described above. The sealing members can be made of rubber or other suitable materials.

Additionally, in some embodiments, a sealant or other adhesive (e.g., butyl) can be used to bond overlapping pan portions of first PV module-pan assembly 560A and second PV module-pan assembly 560B. Second PV module-pan assembly 560B and third PV pan-module assembly 560C can be overlapped in a similar manner as first PV module-pan assembly 560A and second PV module-pan assembly 560B. Additional PV module pan assemblies can be added as desired. In certain embodiments, grooves (e.g., channels, indents, recesses, ridges) can be formed in first edge portions 568 and second edge portions 569 that contact and can couple with each other when overlapped. Such grooves can help reduce or prevent capillary action of moisture or water between pans, for example, in an up-roof direction. In some embodiments butyl caulk or sealant can be included between the overlapped sections.

Non-PV roof pans can be used as dummy modules or transition pans for areas where no PV modules are desired or needed, and/or at the transition to an eave or a ridge. Non-PV roof pans 510 can be installed on exposed edge portion of pan 520 of PV module-pan assembly 560. For example, as shown in FIG. 8 showing a side view of an up-roof portion of a building PV integrated system, lower edge portion of non-PV pan 510 is positioned on exposed first edge portion 568 of PV module-pan assembly 560. Spacer 565 (e.g., filler, offset, support, batten, pad) can be positioned between exposed first edge portion 568 and lower edge portion of non-PV roof pan 510 to elevate non-PV roof pan 510 to a uniform or substantially uniform height as PV module 501. In certain embodiments, an opposing edge portion of non-PV roof pan 510 can extend under flashing 567 or a ridge cap depending on where the assembly with respect to features of the roof.

FIG. 9A shows a down-roof portion of a BIPV system according to various embodiments. In the system shown in this figure, Z-shaped (non-PV) pan 580 can be positioned at a bottom edge of PV module-pan assembly 560 such that first leg 582 of Z-shaped pan 580 extends in an up-roof direction underneath overhang or ledge portion 569 of PV module-pan assembly 560. Second leg 584 of Z-shaped pan 580 extends in a down-roof direction towards eave or gutter of roof R. Second leg 584 is positioned on spacer 565 to elevate Z-shaped (non-PV) pan 580 to a uniform or substantially uniform height as PV module-pan assembly 560. Middle body portion 586 (e.g., wall portion) extends between or couples the two leg portions, first leg 582 and second leg portion 584. Middle body portion 586 extends in a direction generally transverse or perpendicular to roof surface R when mounted to either PV module-pan assembly 560 or spacer 565. Middle body portion 576 can fit within gap 572 between pan structures, and can prevent PV module-pan assembly 560 from sliding down-roof (e.g., provides a stopping surface).

In various embodiments, a vent such as vent 590 (e.g., louvered vent, coravent, vented batten) is provided in front of spacer 565 at eave portion of roof R to allow air to flow through space 565 and underneath PV module pan assemblies 560. FIG. 9B shows in more detail a portion of an eave portion including perforated or caged vent cover 592 usable with various embodiments described herein. Air can flow or enter through such vent cover 592 and vent 590 and flow under PV module pan assemblies or between PV modules and pans of PV module pan assemblies.

Assembly of Building Integrated Photovoltaic Systems

FIGS. 10A-10H show an exemplary installation of BIPV system 1000 on building 1002 (e.g., roof surface of a home) including one or more features or components (e.g., roofing components, transition pans, PV module assemblies, roof pans, underlayment layers), in whole or in part, according to various embodiments of the present technology. BIPV system 1000 includes columns of roof pans 1010 and PV module-pan assemblies 1060 secured together via one or more standing seams (each PV module-pan assembly 1060 being a coupled structure of PV module 1001 and PV pan 1020). The columns of PV module-pan assemblies 1060 can further include down-roof transition pans 1091 and up-roof transition pans 1089 at eave and ridge portions, respectively, of roof surface 1003. BIPV system 1000 can be positioned or mounted on roof surface 1003, either directly to the wooden roof deck or over an existing layer of composition shingles. Intermediate layers of insulation (e.g., isoboard), batten, moisture, and fire protection layers can be laid upon roof surface at least in part below BIPV system 1000. The roof and/or roof surface 1003 of building 1001 can include various components including ridge cap 1093, edge trims 1095, flashing 1097 (e.g., rake, eave, ridge), vents, and gutters.

FIGS. 10B-10H are a series of figures showing an exemplary installation sequence of BIPV system 1000 and other various roofing components according to various embodiments. In some aspects, eave flashing 1097 can be installed onto existing roof surface 1003, which can be composition shingle roof or roof deck. Next, side edging or trimming 1095 can be applied to sides of roof surface 1003.

Layers or rows (e.g., battens) of insulation 1005 (e.g., foam, polyisocyanurate foam) can be installed on portions of roof surface where columns of roof pan (e.g., metal pans) are to be positioned. As noted above, one or more underlayment or other intermediate layers 1007 can be positioned between deck and insulation or insulation and roof pans. Then roof pans 1010 can be laid on top of insulation layer 1005 and/or intermediate layer 1007 and secured with staples, nails, screws or other suitable fasteners. Next, one or more rows of vented battens 1092 (e.g., metal, foam, polyisocyanurate foam) are secured to roof surface at down-roof and up-roof end portions (e.g., by the eave and ridge, respectively) in areas of roof surface 1003 configured to include PV module-pan assemblies 1060.

Down-roof transition pan 1091 can be installed on portion of vented batten 1092 adjacent side of previously installed roof pans 1010. PV module-pan assemblies 1060 are installed, with first PV module-pan assembly 1060A lapped onto a rear or up-roof portion of down-roof transition pan 1091. Second PV module-pan assembly 1060B is lapped onto the rear or up-roof portion of first PV module-pan assembly 1060A. Next, up-roof transition pan 1089 is positioned onto and lapped onto rear or up-roof portion of second PV module-pan assembly 1060B. As shown, two or more (e.g., additional) columns of transition pans 1089, 1091 and PV module-pan assemblies 1060 are similarly installed forming PV array of three columns and two rows of PV modules. In other embodiments, different configurations of PV modules can be included as desired.

Finally, a further layer of insulation 1005 and optional intermediate layers 1007 is installed on second side of the array formed by PV module-pan assemblies 1060, and corresponding columns of non-PV roof pans 1010 are positioned and mounted thereon as on other side of roof surface 1003. Flashing 1097 (e.g. rake flashing) can be installed onto sides of the roof surface (e.g., on the side edging or trimming). Finally, ridge cap 1093 can be installed over ridge. In certain embodiments, a ridge vent can be provided or installed within ridge cap 1093 as described in more detail below.

Supplementary PV Array Hardware

Various aspects of the present disclosure further describe components of structures that can aid in the installation and operation of BIPV systems, including but not limited to, grounding clips and wiring tunnels. In particular, in some embodiments as described in more detail below, one or more grounding members or clips for the PV modules can be positioned under seam covers in contact with a plurality of the seams. In some embodiments, cables or conduits can run along the seams under cover. In other embodiments, cables or conduits can be run along the outer surface of cover and a second cover can be positioned over a first seam cover to conceal cables.

FIGS. 11A-11H show various views of grounding clips 1100 configured in accordance with certain embodiments described herein. In various embodiments, grounding clips 1100 may be used in addition to mounting clips 432. Grounding clip 1100 can be made of stainless steel or other suitable metals or materials. In some embodiments, grounding clip 1100 can be manufactured from a sheet metal stamping process. In application, grounding clips 1100 can provide for structural stability and support to non-PV pans, PV pans, and other standing seam elements on a PV array system. Grounding clips 1100 can also electrically ground such structural elements such that accumulated charge, voltage, or static electricity is drawn away from and does not affect PV modules 1122 supported in the PV array system. In other words, grounding clips can electrically isolate standing seams of structural support pans, as well as rails of PV modules, from electrically conductive and solar energy collecting PV modules.

In various embodiments, grounding clip 1100 includes one or more teeth (e.g., projections, tabs, protrusions, 1104, 1108, 1110) configured to cut or “bite” into standing seam portions 1120 of adjacent, lapped, or overlapped pans (e.g., scrape through a paint coating of the pans or pierce or engage into the pans). Grounding clips 1100 can thereby bond support pans, including both PV module pans and non-PV pans (e.g., roof pans, dummy modules, transition pans,) together. Grounding clip 1100 can bond two panels lapped or positioned side to side as shown in FIG. 11F. As shown in FIG. 11G, grounding clip 1100 can also couple and electrically ground four PV pans 1122 where their standing seams 1120 overlap. In various embodiments, the seam cap may fit over bonding clip 1100.

In some embodiments, particularly shown in FIGS. 11A and 11B, grounding clip 1100 includes body portion 1102 adapted to be inserted between standing seams 1120 of at least two lapped, adjacent, or side-by-side panels 1122 or pans. As shown, inner teeth 1104 extending from opposing side portions of body portion 1102 are configured to engage inner surfaces of lapped standing seams 1120 adjacent to and facing each other. Further, grounding clip 1100 can include hemmed, bent, or curved tab portions 1106 that extend around or over top or upper portions of standing seams 1120 or similar structures. Bent or curved tab portions 1106 can include pair of outer teeth 1108 for engaging outer surfaces of corresponding lapped standing seam 1120 portions adjacent to and facing laterally opposite directions.

Grounding clips 1100 can electrically ground pans 1120 together when installed, directing electrical charge (e.g. static electricity not necessarily generated by PV modules 1122) away from the PV array system to ground. As shown in FIG. 11D, outer teeth 1108 can engage lapped standing seam 1120 portions of two pans, thus grounding two pans together when installed. Similarly, inner teeth 1104 engage paired standing seams 1120 of two pans, with body portion 1102 in between standing seams 1120. Grounding clip 1100 can be configured or sized such that a seam cap can be installed over grounding clip 1100. FIGS. 11E and 11F show an installation of grounding clip 1100 for grounding four lapped standing seams 1120 together, with FIG. 11F showing the positioning of grounding clip over four standing seams 1120 of pans holding PV modules 1122, and with FIG. 11E showing the engagement of grounding clip between four standing seams 1120 after installation. As shown in FIG. 11E, outer teeth 1108 can engage lapped standing seam 1120 exterior face portions, while inner teeth 1104 engage paired standing seams 1120 interior face portions, of two pans, with body portion 1102 in between standing seams 1120.

In certain embodiments, particularly shown in FIGS. 11B, 11C and 11H, grounding clip 1100 includes body portion 1102, pair of inner teeth 1104 extending from opposing side portions of body portion 1102, and curved tab portions 1106, and can also include additional projections, referred to as secondary outer teeth 1110, as well as wings 1112 extending from the ends of curved tab portions 1106. Secondary outer teeth 1110 project laterally outward away from the body portion 1102 of grounding clip 1100. Secondary outer teeth 1110 can be configured to cut or “bite” into or engage seam cover or cap as described above, seam cover being positioned over coupled or interlocked standing seams 1120. Wings 1112 can provide for a further frictional interface or tension spring to secure grounding clip 1100 in place with standing seams 1120.

FIGS. 12A-12C show views of conduits, cables, or wires 1200 of PV system extending or running beside seam covers or caps 1204. Color matched trim piece or secondary cover 1202 can be secured or snap-locked to seam cover 1204 or cap to conceal conduits or wires 1200. In certain embodiments, wire clip 1206 can be secured beside seam cover or cap 1204 under secondary cover 1202 to further secure or hold PV conduits, cables, or wires 1200. Wires 1200 can electrically connect with electrical outlets or other such connections (not shown) of PV modules 1201 to interconnect solar panels together as a PV system. Secondary cover 1202, similar to seam covers or caps 1204, can be configured to connect either or both of non-PV pans and PV pans (along with PV modules, dummy modules, or roof pans, as appropriate) together with a generally uniform appearance.

Wiring Layouts

FIGS. 13A-13M show various examples of portions of wiring systems (e.g., wire management, wire solutions, electrical circuits, configurations, connections, routes, conduits, or pathways) for electrically coupling or connecting PV modules 1301 of PV module-pan assemblies 1360 (e.g., column to column, in a column, in East-West or North-South directions) as part of BIPV system 1300 according to various embodiments. As noted above, one or more channels or pathways can be tunneled or cut through portions of insulation or insulation layers to run PV wires. In various embodiments, micro-inverters, DC optimizers, or other module-level electronics can optionally be electrically connected to one or more of PV modules 1301 as part of overall array and BIPV system 1300.

As shown in FIGS. 13A-13C, BIPV system 1300 can include columns and rows of PV module-pan assemblies 1360, upper transition pans 1389, (e.g., up-roof) and lower transition pans 1391 (e.g., down-roof), and non-PV or roof pans 1310. FIG. 13B shows a portion of BIPV system 1300 with PV modules removed for clarity, showing that columns of PV modules of a PV array can be serially connected by electrically connecting (“stringing up and down”) the columns from one junction box 1375 to next junction box 1375. Respective columns can be connected by running wire under either or both of upper transition pans 1389 or lower transition pans 1391, or under lapped portions of PV module-pan assemblies 1360.

Various wiring arrangements are possible for any given array in BIPV system 1300. FIG. 13C shows an example of column-to-column stringing within BIPV system 1300 array (e.g., under lapped portions of PV module pan assemblies 1360A and 1360B). FIG. 13D shows column-to-column stringing at top of array (e.g., under up-roof transition pans 1389, here semi-transparent, above array columns). Further, the transition from conduit 1340 to exit the array can be routed through channel 1342 formed in insulation layer under the adjacent column of non-PV pan as shown in FIGS. 13D-13E. Conduit 1340 can then exit out through rake 1344 of roof. In other embodiments, conduit 1340 can be run vertically through to the roof eave and exit through slot or opening 1380 in eave as shown in FIGS. 13F-13G. In certain embodiments, two or more arrays on opposing sides of roof ridge can be connected by having conduit transition at ridge of roof that wires from each of arrays run to as shown in FIG. 13H.

FIG. 13I shows a wiring schematic for exemplary array 1300 in FIG. 13B. In this schematic, junction boxes are strung together along the length of each column and at North-South ends of the array, optionally connected beneath transition pans. FIG. 13J shows an exemplary wiring schematic of array 1300 of PV modules with single junction boxes, stringing all PV modules of array 1300 in series. FIGS. 13K-13M show exemplary wiring schematics for stringing or connecting PV modules having two separate junction boxes (V+ and V−). PV modules of these arrays can be “handed” or polarized as shown. FIG. 13K shows a schematic connecting positive and negative poles of PV modules with alternating short and long electrical connections. FIG. 13L shows connecting positive and negative poles of PV modules with short electrical connections laterally and longitudinally for poles that are relatively proximate to each other in array 1300. FIG. 13M shows connecting positive and negative poles of PV modules with a diagonal electrical connections within each row and short connections between rows of array 1300 to connect all PV modules in series. Thus, junction boxes can be positioned accordingly such that internal PV wires run to positive and negative junction boxes at terminal ends of each. Such arrangement of junction boxes can reduce internal and external resistance and the amount of copper wiring or bussing required for each PV module and for connecting PV modules in array 1300. Accordingly, such arrangement can also lower manufacturing cost, installation costs, or improve efficiency. All of the wiring schematics considered may further include a home run to connect array 1300 to a respective electrical grid (e.g., the customer's main electric panel).

FIGS. 14A-14D show other wiring solutions or pathways that can incorporate structural accommodations in support pans as part of PV pan-module assemblies 1460. For example, holes or other openings 1400 can be made in seams 1414 or other pan portions of PV module-pan assemblies 1460 such that wiring 1403 can be routed from column to column via such openings 1400. Grommet seals 1402 (shown here as exploded from opening 1400) can be positioned into openings around wires to seal opening 1400 after routing.

In some embodiments, particularly in configurations as seen above in FIGS. 3A-3C and 4A-4D, wires can be passed or routed column to column around end portions of overlapped portions of PV pans in column. For example, as shown in FIGS. 14B-14D, wires 1403 can be wrapped around up-roof seam end portions of two adjacent PV module pan assemblies 1460A, 1460B. As shown, wires 1403 can be understood to be located on the undersides of PV module pan assemblies 1460A, 1460B, or alternatively resting on PV pans of PV module-pan assemblies 1460 positioned to be between an upper surface of PV pans and a lower surface of PV modules connected thereto. Down-roof end portions of each PV module pan can include recessed portions 1405 (e.g., cavities, tunnels channels) that can be spaced over wires 1403 when lapping PV module-pan assemblies 1460 onto each other.

FIG. 14E shows an exploded view and FIG. 14F shows a perspective view of PV module-pan assembly 1460 according to various embodiments. Assembly 1460 includes exemplary PV pan 1420 that holds PV module 1401 (with PV module 1401 being transparent for this illustration). FIG. 14G shows a bottom perspective view of PV pan 1420. In these views, PV pan 1420 is seen with a gap in the lower surface, forming a workspace between the main trough portion of PV pan 1420 and support bar 1429. Moreover, PV pan 1420 does not have a central or middle rail or support leg, providing for more room for electronics or wire management. In the space between the main trough portion of PV pan 1420 and support bar 1429, multiple wiring routes can be laid allowing more room for cables, better air flow, a wide opening for symmetric or asymmetric wiring, and other conveniences in installation. Further, support bar 1429 can be used as a surface for nailing down or securing the edge of PV pan 1420, and the overall shape of PV pan 1420 can be easier to manufacture. PV module 1401 can be any solar cell laminate as considered herein to be a bonded or adhered (e.g. with a sealant bead) to PV pan 1420. In an array of PV pans 1420, wiring/cabling channels can be aligned with support bars 1429 facing each other across rows of PV module-pan assemblies 1460.

Phase Change Material Aspects

FIGS. 15A-15D are top perspective, exploded, section, and detail views, respectively, of PV module-pan assembly 1560 usable with building integrated PV systems (e.g., system 200) as described herein according to various embodiments. FIG. 15A shows a perspective view of completed PV module-pan assembly 1560 while FIG. 15B shows an exploded view of the same. PV module-pan assembly 1520 includes PV module 1501 bonded to pan 1520. Pan 1520 can include standing seams 1524 on opposing side portions for coupling pans 1520 with other pans (e.g., other PV pans, non-PV pans, roof pans, etc.) as noted above. Standing seams 1524 can be monolithically or separately attached/formed components. Standing seams 1524 can extend perpendicular to planar surface portions of pan 1520, extend at a non-perpendicular angle, and/or be hemmed to round edges. For example, standing seams 1524 can be hemmed inward or medially relative to opposing side portions of the pan. In other embodiments, pans 1520 can include inverted seams.

Referring to FIGS. 15A-15D together, pan 1520 includes first substantially planar surface 1532 (e.g., upper or top surface portion) on which PV module 1501 is mounted. First substantially planar surface 1532 includes opposing substantially planar shoulder portions 1546 that PV module 1501 is positioned or configured to be positioned on. Further, pan 1520 can be bonded to first substantially planar surface 1532 via adhesive 1544 (e.g., strip(s), patch(es), pad(s)) as noted above. Pan 1520 can include recessed portion 1528 (e.g., cavity, lower portion), where recessed portion 1528 includes second substantially planar surface portion 1530 (e.g., lower or bottom surface portion) positioned below or under first substantially planar surface 1532. First substantially planar surface 1532 and second substantively planar surface 1530 can be spaced apart by sidewall portions. While shown as being substantially planar, either of first substantially planar surface 1532 and second substantively planar surface 1530 can also include projections, bumps, or other non-planar features. Further, in some embodiments, pan 1520 does not include second substantively planar surface 1530 portion, such that pan 1520 (and by extension, at least a portion of underside of mounted PV module 1501) can be open to the roof or roof surface on which pan 1520 is mounted.

PV module 1501 can be bonded or otherwise secured to pan 1520 using known techniques. For example, PV module 1501 can be bonded with adhesive 1544 such that a water-tight or substantially water-tight seal is provided between PV module 1501 and pan 1520. In certain embodiments, strips or pads of VHB tape or other suitable material of a desired height can be applied to pan 1520 to set a desired height of PV module 1501. Adhesive or sealant 1544 can then be applied, and PV module 1501 can be set on top of the adhesive and VHB tape to bond PV module 1501 to pan 1520 at the desired height.

PV module-pan assembly 1560 can include one or more active or passive cooling or heat transfer features. In certain embodiments, the PV system includes one or more fans configured to provide airflow underneath PV modules 1501. In other embodiments, PV module-pan assemblies 1560 can include one or more heat sink features (e.g., fins), thermoelectric devices (e.g., materials for cooling), and/or layer or sheet of heat storage materials 1534 (e.g., phase change materials), where in many aspects, heat storage materials 1534 have a relatively high heat capacity as compared to other components of a BIPV system.

PV module-pan assemblies 1560 can include one or more electrical components for electrically connecting PV modules 1501 to an overall PV system, and further, for example, to a household electrical system to provide power to the home. The electrical components can include, but are not limited to, wires 1525, junction boxes 1538, and connectors 1526 (e.g., MC4 connectors). Many of these electrical components are located or pass under PV module 1501. Conventional PV electrical components can be rated or certified for eighty-five degrees centigrade (85° C.). In certain areas, due to increased ambient temperatures and/or operation of BIPV systems, the area under PV modules 1501 may approach and or even exceed this temperature. Therefore, improved heat transfer features can reduce the operating temperature to a desired level and result in improved safety and efficiency of PV modules 1501 (e.g., electrical components).

One or more layers or sheets of heat storage material 1534 can be positioned within recess portion 1528 of pans 1520. Heat storage material 1534 can be, for example, a phase change material such as BioPCM™. Such phase change materials can absorb heat and thereby transition between or change phases (e.g., when reaching or exceeding a melting or freezing temperature or boiling point) from a first phase to a second phase (e.g., from solid to liquid, from liquid to gas, from solid to gas) without raising a temperature of the air around the phase change material during the phase change. For example, heat storage material 1534 can absorb heat from operating PV modules 1501, electrical components, and/or the ambient environment temperature. As heat storage material 1534 reaches a characteristic melting or sublimation temperature (e.g., melting peak) as a result of absorbing heat, it undergoes a phase change. When the temperature of heat storage material 1534 is lowered or passively drops past the phase change temperature, the reverse occurs (e.g. solidification, condensation, or deposition). Further, heat from heat storage material 1534 can be released when phase change material returns to the first phase, for example, when a heat source is removed or ambient temperature decreases.

In addition or alternatively, phase change materials can also be wrapped around the electrical components (e.g., wires, cables, connectors, etc.) in place of or in addition to a phase change material layer placed in a pan.

During a phase change, phase change material remains at a steady or near constant temperature as the phase change material transitions between phases until the phase change material completes or substantially completes the phase transition. During the phase change material phase transition, the temperature of the space or air around the phase change material does not substantially raise even as the temperature of the space or air around it continues to absorb heat. The choice of heat storage material 1534 for any given implementation can be optimized based on expected temperatures from ambient environment, electrical components, and/or PV modules 1501. As the temperature of PV modules 1501 or ambient environment is lowered or removed (e.g., when the sun sets, in the evening), phase change material can return or transition back from the second phase to the first phase (e.g., releasing heat into the ambient air or surroundings when ambient temperature and temperature under the PV modules is lower). By returning to the first phase prior to the next day, when the temperature is once again expected to exceed a desired temperature (e.g., of PV modules 1501 or electrical components), phase change material is ready to absorb heat again and undergo the process (phase change) in response to increased heat so the cycle can be repeated.

As an example, during operation certain BIPV systems can result in an increase of up to or about fifty degrees centigrade (50° C.) over ambient (e.g., in areas under PV modules 1501). In certain locations, temperatures can approach about fifty degrees centigrade (50° C.) ambient or above, which can lead to a temperature of about one hundred degrees centigrade (100° C.) under PV modules 1501. As noted above, certain electrical components are generally rated for about eighty-five degrees centigrade (85° C.). Therefore, in this example, temperatures above about thirty-five degrees centigrade (35° C.) ambient can result in potentially reaching or exceeding the temperature rating on certain electrical components (e.g., in an area under PV modules 1501) during certain times of the day.

Generally, phase change material can return to the first phase after transitioning to the second phase (e.g., re-freeze or become solid or liquid again). In order for the phase change material to return to the first phase from the second phase, the material may need to have a characteristic melting or freezing temperature (e.g., from liquid to solid) above an expected evening or night temperature (highest) in a location where BIPV system is installed. For example, if the melting or freezing temperature of the phase change material is below that of the highest expected evening or night temperature, the phase change material may not be able to re-freeze or return to the first phase when ambient temperature exceeds the freezing temperature.

In certain embodiments, it can be desirable to choose a phase change material having a melting or freezing temperature that is closer to a maximum operating temperature of PV modules 1501 and/or electrical components (e.g., about 85° C.) than that of the highest expected ambient evening or night temperature where BIPV system is installed. For example, if the phase change material undergoes a phase change at a temperature of about forty degrees centigrade (40° C.) in a location where the ambient evening temperature is about thirty-five degrees centigrade (35° C.), then the transition from the first phase to the second phase can occur earlier in the day than desired, and consequentially reduce the amount or time of heat protection, relative to choosing a phase change material with a temperature closer to the maximum operating temperature. In other examples, heat storage materials 1534 can have characteristic phase change temperatures (e.g., melting points) from about sixty degrees centigrade (60° C.) to about eighty degrees centigrade (80° C.), from about sixty degrees centigrade (60° C.) to about seventy-five degrees centigrade (75° C.), about sixty degrees centigrade (60° C.) to about seventy degrees centigrade (70° C.), or about sixty-five degrees centigrade (65° C.) to about seventy degrees centigrade (70° C.). Such embodiments of heat storage materials 1534 can provide improved or increased heat transfer. In certain embodiments, the phase change temperatures can be lower or higher depending on the ambient temperature or maximum operating temperatures.

Further, in certain embodiments, the phase change materials can decrease the change in temperature between peak and minimum temperatures (e.g. the delta between expected maximum and minimum temperatures) of PV modules 1501 and electrical components. This can reduce the amount of cycling or maintain a more steady temperature, which in turn can improve reliability of the PV modules and electrical components, as well as increase efficiency.

As shown in FIGS. 15B-15D, heat storage material 1534 (e.g., phase change material) can include pockets or pouches 1536 configured to hold the actual phase change material inside. Such pouches 1536 can hold phase change material such that when the material transitions, for example, from a solid to a liquid or liquid to a gas, the material remains contained within. Shown in FIG. 15C (a cross-sectional view taken along the line F15C in FIG. 15A), pouches 1536 can form series of peaks or ridges 1540 (e.g., bumps, projections) and valleys 1542. Such a structure can also provide channels through which air can flow under PV modules 1501 through heat storage material 1534 layer. Junction box 1538 can connect to PV modules 1501 through a hole or cutout region of heat storage material 1534.

In certain embodiments, shown in FIG. 15D, peaks of pouches 1536 can contact or further support PV modules 1501 above pan 1520 or roof surface. In other embodiments, a gap can be provided between underside of PV modules 1501 and layer of heat storage material 1534. In some embodiments, heat storage material 1534 layer can be inverted such that peaks 1536 are positioned against the second surface of pan 1520 or roof surface, and planar surface portion of heat storage material 1534 is oriented towards underside of PV module 1501.

Supplementary PV Array Variations

FIGS. 16A-16I are schematic diagrams showing wiring options for solar cell sections 1600 of a PV module accounting for shading caused by standing seams 1614. With standing seams 1614 extending upward above a substantively uniform plane of a PV module, at various times during the day, as the angle of incident sunlight changes (either or both of altitude and azimuth angles) standing seams 1614 can cast a shadow and shade a portion of solar cell sections 1600. The resulting power loss from a set of solar cell sections 1600 is proportional to the area under shade. Using conventional wiring techniques, when shading occurs even more power can be lost due to the shaded solar cell sections 1600 of a PV module limiting the overall current in the PV module, making the entire PV module less efficient. Accordingly, the manner in which solar cell sections 1600 can be set up to include bypass circuits such that solar cell sections 1600 which become shaded can be shunted or bypassed while under shade and not act as a power sink while shaded. These arrangements of solar cells are referred herein to as shade tolerant.

FIG. 16A shows a set of six solar cell sections 1600, in two sets of three wired in parallel and in series (referred to as a shingling arrangement), and with standing seam 1614 proximate to one side of the set of solar cell sections 1600. By orienting solar cell sections 1600 as shown, solar cell sections 1600 can be connected in series within one sub-string column and connected in parallel across adjacent sub-string columns. Solar cell sections 1600 closest to standing seam 1614 will tend to receive the most shading from standing seam 1614. When this occurs, first bypass diode 1606 and second bypass diode 1608 allow for bypassing of one or the other of the set of three solar cell sections, depending on which section is shaded. This arrangement can thereby limit loss of current to the shaded area only.

FIG. 16B shows a set of three solar cell sections 1600 wired in series, with panel diode 1602 in line with solar cell sections 1600 connecting to an electrical grid, and with standing seam 1614 proximate one side of the set of solar cell sections 1600. Solar cell section 1600 closest to standing seam 1614 will tend to receive the most of a shade pattern due to shadows cast by standing seam 1614. Bypass diode 1604 is positioned in-line between solar cell sections 1600 proximate to standing seam 1614, and can allow for the bypass of solar cell sections 1600 proximate to standing seam 1614 such that current loss is limited to one-third (⅓) of the power delivered by the overall module.

FIG. 16C and FIG. 16D show embodiments and arrangements applying cell string optimizers 1610 within the circuit of solar cell sections 1600. FIG. 16C shows an embodiment with one optimizer 1610 per solar cell sub-string and FIG. 16C shows an embodiment with one optimizer 1610 per every two solar cell sub-strings. Optimizers 1610 can be embedded within a solar panel module, either in a junction box or within the laminate. Optimizers 1610 help to limit the shading loss of shaded solar cell sections 1600 by maximizing performance of each sub-string with maximum power point tracking (MPPT). Optimizers 1610 can minimize or eliminate mismatch loss between sub-strings that are under a shade pattern and sub-strings that are not. In some aspects, a single optimizer can be used with a long solar cell sub-string (e.g. shown in FIG. 16B) or with a short solar cell sub-string (e.g. shown in FIG. 16A), depending on the operating voltage range of optimizer 1610.

FIGS. 16E, 16F, 16G, 16H, 16I, and 16J show various embodiments of solar cell section 1600 layouts that can mitigate loss due to shading, in situations where shade patterns on one or more sub-strings of solar cell sections 1600 turn on bypass diode(s) 1608. (Standing seams 1614 are not shown in these Figures for clarity.) FIG. 16E shows a three bypass diode 1608 configuration where solar cell sections 1600 (sub-strings) are connected to one junction box 1616 that is positioned close to an end of PV module. FIG. 16F shows a three bypass diode 1608 configuration where solar cell sections 1600 are connected to two junction boxes 1616 (where two diodes 1608 are directed toward one of junction boxes 1616) that are positioned at opposite ends of PV module respectively. FIG. 16G shows a three bypass diode 1608 configuration where solar cell sections 1600 are connected to one junction box 1616, all being positioned proximate to the middle of PV module. This arrangement can be more energy efficient than configurations with two sub-strings per diode installations.

FIG. 16H shows a two bypass diode 1608 configuration where solar cell sections 1600 (sub-strings) are connected to one junction box 1616 that is positioned close to an end of the PV module. FIG. 16I shows a two bypass diode 1608 configuration where solar cell sections 1600 are connected to two junction boxes 1616 positioned at respective opposite ends of the PV module. FIG. 16J shows a two bypass diode 1608 configuration where solar cell sections 1600 are connected to one junction box 1616, all being positioned proximate to the middle of PV module.

A further embodiment shown in FIG. 16K considers the use of laminated and reflective surfaces on standing seam 1614 in combination with optical texture film 1640 alongside both longitudinal edges of PV module 1601 surface. With sunrays 1650 at a given angle relative to surface of PV module 1601, shade region 1601 a is created due to the relative height of standing seam 1614. As shown, the surface of standing seam 1614 can be reflective, due to either a light redirected film and/or texture of the seam, to redirect sun rays 1650 a, 1650 b to shaded region 1601 a of PV module 1601. Specifically, rays 1650 a can be directly incident on standing seam 1614 and then reflect or refract off of the surface of standing seam 1614 onto shade region 1601 a of PV module 1601. Alternatively or additionally, rays 1650 b can be directly incident on optical texture film 1640 and then reflect or redirect onto the surface of standing seam 1614, then further reflecting or refracting onto shaded region 1601 a of PV module 1601.

FIG. 17 shows an embodiment of PV column 1700 of a solar panel array where the PV column is configured to take advantage of convection and related heat transfer. On any given roof or structure, one or more PV panels 1702 are positioned between lower transition pan 1704 and upper transition pan 1706. The surface of lower transition pan 1704 can be coated with a thin film or other material that has a high solar reflectance and a low thermal emittance, which can be referred to as a “cool coating” material. Solar energy incident on lower transition pan 1704 can convert to become about 50% heat reflecting from lower transition pan 1704, or in other words, absorbing about 50% of the heat from incident solar energy. PV panels 1702 have the primary function of converting incident solar energy into electricity, absorbing about 70% of the heat from incident solar energy. The surface of upper transition pan 1706 can be coated with a thin film or other material that has a low solar reflectance and a low thermal emittance, a selective coating similar to or the same as the coating of for a solar thermal collector. Thus, for solar energy incident on upper transition pan 1706, about 90% of the heat from incident solar energy can be absorbed.

The transition along the slope of the surface or roof on which PV column 1700 is installed can thereby create a temperature gradient, hotter toward the bottom and cooler toward the top, such that convective air motion 1708 is increased or supplemented. Convective air motion 1708 can aid in cooling the overall solar panel array of which PV column 1700 is a part of, as well as an underlying roofing surface.

FIG. 18 shows a schematic representation of a pair of vent modules according to embodiments. Two vent modules are shown in FIG. 18, active vent module 1810 and passive vent module 1820. Both versions are configured to draw air from underneath PV modules 1801 of a BIPV system without penetrating underlying roof 1800 or ventilating an attic beneath roof 1800. Either embodiment of the vent can be positioned at, along, or under top rows of roofing structures (e.g. underneath PV modules 1801) proximate to ridge 1805 of roof 1800 such that the air drawn by either active vent module 1810 or passive vent module 1820 exits underlying roof 1800 structure before reaching ridge 1805. Active vent module 1810 can include fans 1815 installed along its width to draw air into and through active vent module 1810. Passive vent module 1820 can include vent slots 1825, which can be either horizontal or vertical slots along width of passive vent module 1820.

In further aspects, either active vent module 1810 or passive vent module 1820 can be positioned toward the bottom or eave of roof 1800, to provide for an air inlet. Accordingly, air can be drawn into a space underlying PV modules 1801 by active vent modules 1810 or passive vent modules 1820 at bottom of roof 1800, generally cooling PV modules 1801. Similarly, heated or ambient hot air can egress through active vent modules 1810 or passive vent modules 1820 proximate to top of roof 1800, similarly cooling PV modules 1801.

Built-In/Re-Roofing BIPV Embodiment

As discussed herein, PV modules and assemblies of PV modules and supporting structural pans for PV modules can be integrated so that they make up the main surface of a roof. By having the PV modules be part of the roof, advantages can be obtained in comparison to more traditional “on-roof” arrays that are slightly elevated from the surface of a roof. For example, modules and assemblies that are built-into the framing structure of a roof can be lighter than on-roof installations, at least because the built-in BIPV solar array does not require a second structure above an existing roof. Further, a roof that is being replaced in a re-roofing installation can replace roof pans or tiles with BIPV modules or assemblies, which can be more efficient in reducing the amount of materials needed for a re-roofing installation. Also, electrical connections, junction boxes, and wiring can be generally housed underneath PV modules of BIPV assemblies, optionally within spaces of a supporting structural pan, protecting such components from precipitation, wind, and excess heat, and further hiding such components from an observer so as to make the overall BIPV system visually attractive or uniform.

FIG. 19 is a perspective view of PV module pan assembly 1960 usable with BIPV systems (e.g., system 200, system 1000) as described herein according to various embodiments of this disclosure. Similar to PV module-pan assemblies described herein, PV module pan assembly 1960 includes PV module 1901 bonded to pan 1920. Pan 1920 includes standing seams 1921 for forming interlocked seams with other PV module-pan assemblies 1960 or non-PV roof pans in the same column and in adjacent columns. Pans 1920 and non-PV pans can be overlapped in the same column as described above with respect to PV module-pan assembly 1960. Pan 1920 can also include grooves 1974 on exposed edge portion 1968 to prevent or reduce capillary action (e.g., water from running up-roof at the overlap) at the interface or contact surfaces of the overlapped portions of the PV module assemblies.

FIGS. 20A-20L are various views including top perspective, side, end, and exploded views of another PV module-pan assembly 2860 usable with building integrated PV systems (e.g., system 200, system 1000) as described herein according to other embodiments. Similar to PV module-pan assemblies noted above, PV module-pan assembly 2860 includes PV module 2801 bonded to pan 2820. Pan 2820 can include standing seams 2821 (alternatively referred to as sidewalls) on opposing sides for coupling pans 2820 with other PV and/or non-PV pans as described above. Standing seams 2821 can be monolithically or separately attached and/or formed (e.g. bent or molded) components. Standing seams 2821 can extend perpendicular to the planar surface portions of pan 2820, extend at a non-perpendicular angle, and/or be hemmed to round edges.

Further, PV module assembly 2860 can be provided with overhang and exposed edge portions 2862 (e.g., pan 2820 portions that are not covered by PV module 2801 portions), and installed to overlap other assemblies as described above. PV module assembly 2860 can also include one or more of same or similar features, for example, grooves, channels, ridges, or bumps to prevent or reduce capillary action (e.g., pulling water up-roof between lapped PV module pans). As shown, ridges 2874 can be two or three rows of evenly spaced apart indentations. Electrical connectors 2815 can extend either from underneath portions of pan 2820 covered by PV module 2801 or from edge portions 2862 of pan 2820.

As shown, pan 2820 includes a first substantially planar surface, first surface portion 2863 (e.g., an upper or top surface portion), with one or more openings 2865 formed between leg or support portions 2867 (e.g., strips, ribs). For example shown in FIG. 20F, first substantially planar surface 2863 can include three spaced apart support portions 2867 extending between front and rear substantially planar portions. Pan 2820 includes one or more second substantially planar surfaces, second surface portions 2869 (e.g., lower or bottom surface portions), forming one or more troughs 2871 or valleys when coupled to upper surface portion 2863, shown in FIGS. 20C and 20F. Second surface portions 2869 include upwardly extending sidewalls or flanges configured to be fastened or coupled with corresponding downwardly extending sidewalls or flanges of support portions 2867. In some aspects, the use of first surface portions 2863 and second surface portions 2869, being relatively narrower than a single surface member of the same combined width, can allow for easier manufacture and handling for installation. Further, the widths of first surface portions 2863 and second surface portions 2869 can correspond to and fit with the locations of support portions 2867, providing for more stable assembly. First surface portions 2863 and second surface portions 2869 can be spaced apart accordingly. For example, corresponding sidewalls or flanges of first surface portions 2863 and second surface portions 2869 can be attached with rivets, screws, or other suitable fasteners. In other embodiments, sidewalls or flanges of first surface portions 2863 and second surface portions 2869 can be adhered or welded together.

In other embodiments, instead of separately formed pieces, pan 2820 can be monolithically formed (e.g., a stamped one or two piece pan). While shown as being substantially planar, either of first surface portion 2863 or second surface portion 2869 can also include projections, bumps, or non-planar features. In some aspects, trim 2895, which can be a sealing member or a sealing cover (e.g. a watertight seal), may be attached to interface respective edges of first surface portion 2863 and PV module 2801.

As noted above, pan 2820 can include channels or ridges 2874 formed in or attached to rear surface portion of pan 2820 to prevent or reduce capillary action. Pan 2820 can further include openings 2873 (e.g., apertures) in one or more of sidewalls or flanges to allow wire (e.g., conduit or cables) to be passed through and run alongside an underside of pan 2820 through channels or gaps formed between sidewalls or flanges. Further, in some embodiments, wiring can be attached to the bottom of pan 2820 via one or more clips or other fasteners. Holes and openings 2873 can include grommets 2876, other types of bushings, or other suitable inserts to round out the sharp edges in openings 2873. Wires can be, for example, positive and negative cables from one or more j-boxes 2875 positioned within troughs 2871 and mounted to the bottom of a PV module. J-boxes 2875 can be center mounted or off-center mounted (e.g., more proximate to the sides and/or edges). For example, in certain embodiments, two j-boxes 2875A, 2875B can be mounted in respective troughs 2871 more proximate to opposing sides of pan 2820.

Pans can further include one or more mounting portions 2877 (e.g., feet, brackets, members) to be coupled to roof surfaces. Such mounting portions 2877 can be bent or hemmed from pan portions (e.g., standing seams) or separately formed and attached. Mounting portions 2877 can include L-shaped brackets formed or secured at opposing ends of the pan. In other embodiments, mounting portions 2877 can be formed or secured along a rear or up-roof edge surface of the pan as shown in FIGS. 20M-20Q. For example, mounting portions 2877 can be riveted to or otherwise coupled to recessed or cutout portions of the rear surface portion of pan 2820 to provide improved rigidity and securement. Such mounting portions 2877 can be shaped to track the contour of troughs 2871, or can be arranged and constructed to otherwise form supporting structures for PV module-pan assembly 2860.

In various embodiments, sharp or angled edges of bottom pan portions 2869 or troughs 2871, as well as mounting portions 2877, can be covered or capped (e.g., enclosed, wrapped) with rubber or other types of edge protection 2879 (e.g., tape). Edge protection 2879 can reduce or minimize the potential for sharp edges to fray wires that pass under PV modules 2801 and improve installer safety. In other embodiments, such edges can be hemmed or bent.

As noted above with reference to various embodiments, PV module 2801 can be bonded or otherwise secured to pan 2820. For example, PV module can be bonded with adhesive such that a watertight or substantially watertight seal is provided between PV module 2801 and pan 2820. As shown in the exploded view of FIG. 20D, strips or pads of VHB tape 2881 or other suitable material of a desired height can be applied to pan 2820 (including, for example, other structures connected to pan 2820 such as PV module supports) to set a desired height of adhesive or sealant. Adhesive 2883 or sealant can then be applied in a pattern as shown, and then PV module 2801 can be set on top of adhesive 2883 and VHB tape 2881 to bond PV module 2801 to pan 2820. Further, trim 2895 can be attached at the North-South edges of PV module 2801.

FIGS. 21A-21E show various views of an alternative embodiment for pan 2920 of PV module pan assembly 2860. (PV module 2860 has been made transparent in certain views for clarity.) In this embodiment, center support portion 2967 (also referred to as leg portion) of first surface portion 2863 can be discontinuous. For example, cutout portion or recess 2985 can be formed to provide a pathway for cable, conduits, j-boxes 2875, or wires. Space provided by cutout portion or recess 2985 may eliminate the need for holes or openings to be formed in center support portion 2967 and/or the need to run (e.g., fishing) wires or cables through holes and to pull wires through to an exterior portion of pan 2920. As a result, less time and labor may be required when installing PV module 2801 as part of such PV module-pan assembly 2860. For example, cables or wires from j-box(es) 2875 can come pre-clipped or otherwise secured (e.g., taped, fastened) to PV module 2801 in a desired orientation and position. J-boxes 2875 can be installed with wires extending through cutout portion or recess and secured with clips or other fasteners. In this manner, an additional individual or installer is not necessary to hold cables (e.g., in tension) and to fish or run cables through holes in pan 2920 while one or more individuals set PV module 2801 onto an adhesive. If j-box 2875 and wires are pre-set or installed, then one or more individuals can set PV module 2801 onto pan 2920 without having to hold cables and run them through grommets or holes at the same time to reduce contact with PV module 2801 after being adhered onto pan 2920.

FIG. 22 shows a further embodiment of pan 3020 of PV module-pan assembly 2860. In this embodiment, a PV module (not shown) with “glass on glass” layers can be attached to the pan. Such PV modules (e.g., with improved rigidity relative to single glass layered modules) can be attached to pan 3020 without a third leg or support (e.g., middle, center) between opposing side legs or supports 3067. In other embodiments, other types of PV modules disclosed herein can be mounted onto pan 3020. Further, pan 3020 can include support ribs 3087 extending along the width of pan 3020 (e.g., extending substantially traverse or non-parallel to the longitudinally extending supports) to provide additional rigidity. The configuration and arrangement of support ribs 3087 can provide increased space below PV module and reduced manufacturing costs. While shown as having two j-boxes 2875, in other embodiments, single j-box 2875 can also be provided with pan 3020.

FIGS. 23A-23E show various views of down-roof transition pans 3391 or non-PV pans 3310 (e.g., dummy modules, roof pans) that can be positioned at down-roof end portions of a column of PV module-pan assemblies 3360. As shown in FIG. 23B, the airflow can flow through vented battens 3311 at ridge or up-roof end of a column, which can allow for airflow that enters through eave flashing 3200 to pass under column of PV module-pan assemblies 3160, through vented battens 3311, for example to roof ridge 3250 as noted above. PV module-pan assembly 3360 can be lapped onto planar surface portion 3392 (e.g., up-roof or lower portion) of down-roof transition pan 3391. Down-roof transition pan 3391 can be spaced (e.g. such that transition pan 3391 is coplanar with PV modules 3301) and supported above roof surface 3303 by one or more rows of vented battens 3311. Transition pan 3391 can include planar on-lapped surface 3393 (e.g., down-roof or upper) portion that is raised or relatively elevated above lapped portion 3395 via step 3394, such that non-lapped surface is coplanar or substantially coplanar (e.g., in elevation) with portion of corresponding lapped PV module portion. Non-lapped surface portion 3393 can be same or appear similar to roof pan surfaces or PV modules to provide a more uniform appearance across roof surface 3303. Standing seams 3314 can run along the sides of columns forming structure of overall BIPV system and array, securing adjacent columns and/or rows of PV module-pan assemblies 3360 and/or various non-3310 PV pans to each other.

Similarly to PV module pan assemblies, lapped portion 3395 on the surface of downward transition pan 3391 can include one or more ridges or channels 3374 to prevent or reduce capillary action (e.g., in an up-roof direction). Transition pan 3391 can also include one or more mounting feet 3396 configured to be secured to roof surface 3303 via one or more fasteners. As noted above, transition pans 3391 can also include one or more drains 3397 (e.g., indent or recess features) that can help improve egress of water or other debris (e.g., flowing from vertical seams of column of PV module pan assemblies). Additionally, transition pans 3391 can include corresponding standing seam portions and hemmed portions 3398 for attachment to flashings or other roofing components at eave of roof 3303. Standing seam or hemmed portions 3398 portions can be positioned laterally outward of corresponding seam portions of PV module-pan assembly that can be extended over lapped portion 3395 of down-roof transition pan 3391.

FIGS. 24A-24D show various views of up-roof transition 3389 or non-PV pans 3310 (e.g., dummy modules or roof pans) positioned over or mounted to rows of vented battens 3311 or other spacing layers at ridge portion of roof 3303. As noted above, up-roof transition pans 3389 can be roof pans or appear similar to roof pans having planar surface portion with opposing standing seams 3314 or bent up portions. In other embodiments, standing seams 3314 can be hemmed or bent over. In yet further embodiments, standing seams 3314 can be inverted or bent downward. Up-roof transition pans 3398 can have hemmed over portion 3399 (e.g., U-shaped or hooked edge portion or lip) configured to be positioned adjacent PV module positioned down-roof therefrom. Hemmed edge portion 3399 can reduce or decrease a risk of sharp edges damaging PV modules.

A portion of up-roof transition pan 3389 can be lapped over corresponding down-roof PV module-pan assembly 3360 (e.g., an up-roof portion of a pan) in column. Lapping portion of up-roof transition pan 3389 can be coplanar or substantially coplanar with PV module mounted or bonded onto corresponding down-roof PV module pan assembly 3360. Edge portion (e.g., down-roof hemmed portion) of such lapping portion can be spaced apart from up-roof portion of PV module when lapped. In other embodiments, at least a portion of hemmed portion can abut edge portion of PV module. Standing seams 3314 of up-roof transition pan 3389 can be positioned between (e.g., medially inward relative to) opposing standing seams of PV module pan assembly 3360 on which up-roof transition pan 3389 can be lapped. Up-roof transition pan 3389 can be secured directly to roof surface 3303 or to vented battens 3311 that support up-roof transition pans 3389 above roof surface 3303 (e.g., coplanar with PV module).

FIG. 25A to 25E show an embodiment of columns of PV pans of such assemblies. PV pans 4620 can be pre-installed or mounted to the roof surface without PV modules 4601. PV pans 4620 can have substantially L-shaped mounting portions 4662A, 4662B on opposing lateral side portions of PV pan 4620 for supporting and securing PV modules 4601. PV modules 4601 can be provided with mounting clips 4663A, 4663B (e.g. hinge clips, latch clips) configured to secure PV module 4601 to corresponding mounting portions 4662A, 4662B of PV pans 4620.

Standing seams 4614 can rise between columns of PV modules 4601 mounted to PV pans 4620, as described above. Such standing seams 4614 can include seam covers 4636 that can connect to other structural elements of various PV pans or non-PV pans, as well as provide protection from precipitation or wind flow from getting underneath PV pans 4601.

In embodiments, the first side of PV pan 4620 includes first mounting clip 4663A, a hinge clip, and second side of PV pan 4620 includes second mounting clip 4663B, a latch clip. PV modules 4601 can be dropped in (e.g., rotated or pivoted) onto PV pan 4620 via mounting portions 4662. For example, the first side of PV pan 4620 with first mounting clip 4663A can be secured to first mounting portion 4662A. An installer can push PV pan 4620 in a first direction towards first side of pan 4620 such that first mounting clip 4663A (hinge clip) is secured to first mounting portion 4662A. Next, the installer can drop in the second side of PV module 4601 such that second mounting clip 4663B (latch clip) is secured to second mounting portion 4662B to couple PV module 4601 to PV pan 4620. In order to remove PV module 4601 (e.g., for repair or replacement), PV module 4601 can be pushed in a first direction identified by the arrow A. The installer can then lift second side up and then the first side.

Seamless/Infinity Appearance Embodiment

As disclosed above, in embodiments the top surfaces of adjacent PV modules in a column are substantially coplanar. However in embodiments the top surfaces of adjacent PV modules in a column may be on different planes, i.e. not coplanar. As noted, there are many advantages, both structurally and aesthetically, associated with coplanar top surfaces of PV modules. However, coplanar PV modules may lead to noticeable edges or boundaries between adjacent PV modules in a column. Standard roof pans can be a single piece from eave to peak of a roof and therefore do not have any seams. Therefore, it is an object of the disclosure, and the configurations described below, to orient adjacent PV modules in a way that makes the boundaries between adjacent PV modules substantially unnoticeable, particularly from angles from which a viewer would typically view a roof. Therefore, in these configurations columns of PV modules will have an appearance similar to standard roof pans of adjacent columns. These configurations will herein be referred to as “infinity configurations” because the orientation and positioning of adjacent PV modules create a visual effect, from certain viewing angles, that makes the edges between adjacent PV modules essentially invisible. In embodiments, the PV modules are frameless and are comprised of a sandwich of a top sheet and backsheet protecting center internal PV layers, or are glass on glass. In other embodiments, at least the top surface of the up-roof end does not include any type of frame extending past the top surface. However, in some embodiments, portions of or even the entire PV laminate of the PV module is frameless.

In infinity configurations, an up-roof end portion of a down-roof PV module is positioned to obscure a down-roof end portion of an adjacent up-roof PV module from typical viewing angles. This obscuring creates an infinity effect wherein due to the optical properties of the edge of the frameless PV module, a viewer from a viewpoint where the down-roof edge of an up-roof PV module is obscured, will not easily notice a boundary between the adjacent PV modules. This visual effect further has the advantage of allowing for small misalignments to be unnoticeable because the boundaries between adjacent PV modules are not visible. In such embodiments, this visual effect is achieved by positioning an up-roof end portion of a down-roof PV module a further distance away, in a direction perpendicular to a roof surface, compared to the down-roof end portion of an adjacent up-roof PV module. In embodiments, each PV module in a column may be positioned and oriented so that the boundaries between all adjacent PV modules in the column are not visible from typical viewing angles. This leads to the column of PV modules having a similar appearance to a standard roof pan of similar color. In various embodiments, for adjacent PV modules to be oriented in this matter, the angle of each PV module must be slightly steeper than the roof pitch.

As shown in FIGS. 26A-B, typically a viewer 2699 views a roof from a location on the ground below the eave of roof 2600. In order to see the roof surface, the viewer's eye must be above roof plane 2612 that extends from surface of roof 2600. As noted, in order for the boundaries of adjacent PV modules to be invisible, the down-roof edge of up-roof PV module 2601A is obscured. An infinity plane 2614 extends from a top edge of a down-roof side of up-roof PV module 2601A through a top edge of an up-roof side of down-roof PV module 2601B. For the down-roof edge of up-roof PV module 2601A to be obscured, the viewer must be below infinity plane 2614. If the viewpoint is above infinity plane 2614, then the boundary between up-roof PV module 2601A and down-roof PV module 2601B will be visible because the viewer's line of sight will include down-roof side edge of up-roof PV module 2601A. As shown, an infinity triangle is formed where the roof surface is visible and the boundaries are obscured. The sides of the infinity triangle include roof plane 2612, infinity plane 2614 and the ground. The angle of infinity plane 2614 relative to horizontal is dependent on the sizes of ΔH and G, wherein ΔH is the difference is distance, in a direction perpendicular to roof surface, between top edge of down-roof PV module 2601B and top edge of up-roof PV module 2601A, and wherein G is the distance, also referred to as gap, between edges of adjacent PV modules, as shown in FIG. 26B. Increasing ΔH leads to a less downwardly pointing infinity plane. In embodiments a large ΔH will result in an infinity plane pointing upwards. In embodiments, increasing the distance of gap G will result in a more downwardly pointing infinity plane. AH and G can be set in order to optimize the range of viewing angles with the infinity effect while maintaining other desirable properties of the system, for example properties related to air flow, water, debris management and thermal expansion. In embodiments, ΔH may be from 2 mm to about 6 mm, for example 2 mm or 4 mm. In embodiments, ΔH is less than the thickness of the PV modules or PV laminate. In embodiments, G may be negative or positive and range from −6 mm to 6 mm. For example, as will be discussed below, G may be 0 mm, wherein PV modules are abutting. Further, G may have a negative value, wherein adjacent PV modules are overlapped and ΔH is greater than the thickness of the PV modules. However, other dimensions may be used depending on the pitch of the roof and desired viewing angles for the infinity effect.

As will be discussed below, infinity configurations of PV modules may be implemented as part of embodiments discussed above, and in related applications, relating to Building Integrated PV (BIPV) embodiments and On-Roof embodiments.

FIGS. 27A-27E show views of PV module-pan assemblies including PV pan 2720, which is similar to PV pans discussed above used for coplanar PV modules. As previously noted, PV pans can include a first substantially planar surface 2728 (e.g upper or top surface portion) that PV module 2702 is mounted on. Also, as previously noted, PV pan 2720 can include a second substantially planar surface 2729 (e.g. lower or bottom surface portion) positioned below or under first surface. As shown in FIG. 27A, up-roof end portion 2730 of down-roof PV module 2702 is positioned at a greater elevation relative to first substantially planar surface 2728, and therefore also to the roof surface, as compared to down-roof end portion 2731 of the up-roof PV module. In various embodiments, this difference in elevation will be small, and preferably less than the thickness of PV module 2702. In the embodiment shown, the difference in elevation is achieved through different thicknesses of support members 2732, for example an adhesive and/or pad (e.g., VHB tape), between PV pan 2720 and PV module 2702. Specifically, each PV module-pan assembly includes a greater thickness of adhesive or pad on the up-roof end of PV module pan compared to the down-roof end. In this manner, the up-roof end of the down-roof PV module is angled relative to first surface 2728, with the up-roof end portion further from first surface than the down-roof end. This difference in support height of PV module positions PV modules at an angle relative to roof surface and therefore PV modules are positioned at a slightly steeper pitch than roof surface, as discussed above.

While the embodiment shown in FIG. 27A uses different thicknesses of adhesives or pads to achieve an angled PV module relative to the PV pan, in other embodiments, different methods may be used to angle PV modules relative to PV pans and roof surfaces. For example, in various embodiments, first and second surfaces of the PV pan can be non-parallel to create a sloped or ramped surface. In other embodiments, PV modules can include a layer having different thicknesses along their length, such as, for example, a ramped backsheet. In various embodiments, a protrusion (e.g., a rib, bump, spacer, offset, rail, rib, leg, etc.) can raise an up-roof end portion relative to a down-roof end portion of a PV module as described in more detail below with respect to FIGS. 28A-D. In other embodiments, PV pans may include standoffs, leg support portions, or feet of different heights that elevate up-roof and down ends of PV pan different distances above roof surface.

As shown in the FIGS. 27A-D, in some embodiments, a sealing member 2733 may be positioned between adjacent PV modules. Alternatively, PV module 2702 may be manufactured to include such a sealing member at the up-roof end. Sealing member 2733 is positioned in the gap between the two PV modules 2702. Sealing member 2733 can have a first purpose of providing edge protection during installation. For example, if sealing member 2733 is pre-installed on the up-roof end of the down-roof PV module-pan assembly, an up-roof PV module-pan assembly can be slid into place with reduced risk of a portion thereof contacting and damaging the PV module of the down-roof PV module-pan assembly. Further, sealing member 2733 may prevent unwanted contact of PV modules caused by thermal expansion of PV pans or PV modules. Further, sealing member 2733 may assist with the flow of water and debris over PV modules 2702, and prevent debris from accumulating on the top surface of adjacent PV modules at the boundary between adjacent PV modules, which may hamper the infinity visual effect. In embodiments, for example as shown in FIG. 27B, sealing member 2733 may extend along the entire length of the boundary of adjacent PV modules, i.e. from standing seam 2712 to standing seam opposite standing seam 2712. In various embodiments, sealing member can extend completely, or substantially completely, across a gap between adjacent PV modules. In embodiments, sealing member can include two or more discrete members positioned at two or more discrete locations in the gap between PV modules. Further in various embodiments, two of more discrete members of sealing member may be separated by openings that allow air and water to flow between the ambient and an area between PV module and PV pan.

In various embodiments, sealing member 2733 can be attached to either, or both, adjacent PV modules (e.g., down-roof or up-roof PV module). Further, as noted, sealing member 2733 may assist in the flow of water over the PV modules, and prevent debris from accumulating. For these purposes, sealing member may include surface 2734 creating a slope or ramp between top surfaces of adjacent PV modules 2702. Ramped surfaces 2734 can provide improved removal of water or debris flowing down-roof on top of PV modules 2702. In infinity configuration embodiments including a sealing member, or similar member between adjacent PV modules, the size and position of sealing member, and ΔH and G, are configured so that from desired viewing angles, the sealing member is obscured by the up-roof end of the down-roof PV module. In embodiments, sealing member 2733 does not extend in a direction perpendicular to roof surface beyond a top surface corner of an up-roof end of a down-roof PV module.

In embodiments, sealing member 2733 includes a mounting end 2735 configured to be received between a bottom surface of a PV module 2702 and first substantially planar surface 2728, as shown in FIG. 27A. As shown, sealing member 2733 can include projections on mounting end 2735 to improve connection or mounting onto the PV module. In embodiments, sealing member 2733 is comprised of a resilient material that can easily deform and maintain a seal during thermal expansion and compression of PV modules and PV pans. In embodiments, sealing member 2733 includes a hollow cavity 2736 extending along the length of sealing member. Hollow cavity 2736 allows sealing member to more easily compress in order to accommodate thermal expansion of PV modules, or PV pans. In embodiments, sealing member 2733 substantially seals the gap between adjacent PV modules to prevent or minimize debris from flowing into the space under them. In embodiments, sealing member 2733 does not form a watertight seal between adjacent PV modules and debris or water can flow from top surfaces of the PV modules through gaps to an area below the PV modules, as will be discussed below.

As shown in FIG. 28A, in various embodiments, PV pan 2820A can include protrusion 2807 (e.g., a bump, stop, rail, rib, spacer, offset). Protrusion 2807 can be provided to elevate an up-roof end portion of PV module 2801A relative to a down-roof end portion in the plane of the roof, to create the appropriate angle of PV module relative to PV pan and roof surface for the infinity configuration visual effect discussed above. In embodiments, the down-roof end of PV module 2801A may be supported by a shorter protrusion, or by another means such as adhesive of padding as discussed above. Protrusions can be stamped or otherwise monolithically formed into a surface of the PV module pan 2820A. In embodiments, protrusions can be separately formed pieces or components attached or secured to PV pans.

As shown in FIG. 28A, protrusion 2807 of up-roof end of PV pan 2820A can act as a stopper or bumper for up-roof PV pan 2820B or PV module 2801B. In embodiments, up-roof PV pan 2820B can be lapped over down-roof PV pan 2820A and slid down-roof until contact between PV module 2801B and protrusion 2807 occurs. Therefore, protrusion 2807 may act as a stop or indicator to an installer that up-roof PV module 2801B is in a correct position.

Further, in embodiments, down-roof end of up-roof PV module 2801B may include sealing member 2833. Sealing member 2833 includes slot 2834 configured to receive an end of PV module 2801B. Sealing member 2833 can elastically deform as it is secured onto the edge portion of the PV module. For example, in an uninstalled position, as shown in FIG. 28C, slot 2834 is smaller in height than a corresponding edge portion of PV module 2801B. As sealing member 2833 is installed onto the PV module, slot 2834 elastically deforms as PV module 2801B is received. Slot 2834 can include barbs or other projections 2835 to improve engagement or securement onto PV modules. In embodiments, sealing member 2833 may be made of EPDM rubber molded on a metal body portion to provide rigidity or strength.

As noted above, sealing members, such as shown in FIGS. 27A-C and FIGS. 28A-C, can include a ramped or sloped surface to improve water or debris flow over the modules.

In embodiments, PV modules may be supported above roof surface by more than one PV pan. For example, as shown in FIGS. 29A-D, PV module-pan assembly 2960A may include first PV module 2901A affixed to PV pan 2920A and also include matting tabs 2941 for supporting second PV module 2901B. As shown, PV pan 2920A can include a first substantially planar surface 2932 (e.g., an upper or top surface portion) that PV module 2901A is mounted on. In embodiments, PV module 2901A can be affixed to first surface 2932 as discussed above in a parallel or non-parallel manner. PV pan 2920A can further include a recessed portion (e.g., cavity, lower portion). The recessed portion includes a second substantially planar surface portion 2930 (e.g., lower or bottom surface portion) positioned below or under the first surface 2932. The first and second surfaces can be spaced apart by sidewall portions. While illustrated as being substantially planar, either of the first or second surface portions can also include projections, bumps, or other non-planar features. Further, in various embodiments, PV pan 2920A may not include a second surface portion such that PV pan 2920A (e.g., at least a portion of an underside of mounted PV module) is open to the roof or roof surface PV pan 2920A is mounted on.

As shown second PV module 2901B, positioned down-roof of PV module 2901A and affixed to PV pan 2920B, may be supported on one or more mating tabs 2941 of PV pan 2920A. Mating tabs 2941 extend down-roof from PV pan 2920A. Mating tabs 2941 can include pads 2942 (e.g., EPDM rubber). Mating tabs 2941 support up-roof edge portions of down-roof PV module 2901B at a lifted position higher relative to a down-roof edge portion of up-roof PV module 2901A. As noted above, PV pan 2920A may include means for positioning PV module 2901A at an angle and elevated position for infinity visual effect.

PV module-pan assemblies including mating tabs may be installed as shown in FIGS. 29C-D. As shown, mating tabs 2941 can be inserted between a lower surface of down-roof PV module 2901B and down-roof PV pan 2920B. Mating tab of up-roof PV module pan assembly 2960A is inserted down-roof until the corresponding PV modules 2901A and 2901B abut with each other, or in embodiments a sealing member, as discussed above, contacts both PV modules.

As discussed above, embodiments may include a gap between adjacent PV modules, and gaps may be configured to include or not include sealing members, or the like, which allow for water and air to flow between the ambient and a space below PV module. FIGS. 30A-K shown an embodiment including gaps between adjacent PV modules. PV modules of embodiment shown in FIGS. 30A-K may be coplanar or may be oriented to display an infinity visual effect.

FIG. 30A shows a portion of a roof including PV module-pan assemblies 3060A and 3060B, and lower transition pan 3005 positioned between PV module-pan assemblies 3060B and eave 3013 of a roof. As shown in FIG. 30B, PV pan 3020 includes substantially planar surface shoulder and rib portions 3050A and 3050B for supporting a PV module. In embodiments, adhesive can bond PV module 3001 to the pan 3020, as noted above. In embodiments, PV module 3001 can be snap-locked into pan 3020. In embodiments, PV module can include rails or corresponding standing seams to be coupled with the seams of the pan. As noted above, PV pans can be lapped and include a bump or stop (e.g., protrusion) to indicate proper alignment and spacing. In embodiments, corresponding male and female couplings can be attached to the pan or PV modules to provide proper alignment and spacing.

FIG. 30C shows a perspective view of an embodiment of lower transition pan 3005A. A dummy panel or module 3055 can be attached to lower transition pan 3005A in a similar manner as PV modules are affixed to PV pans, as discussed above. In embodiments, water is allowed to drain through a slot or channel between dummy panel 3055 and the transition pan 3005. Dummy panel 3055 may be positioned relative to adjacent up-roof PV module 3001 to create an infinity visual effect in a similar way as two adjacent PV modules, as discussed above. Specifically, in embodiments, up-roof edge of dummy panel 3055 obscures down-roof edge of adjacent up-roof PV module. Dummy panel can be a color matched to nearby roof pans 3010. In embodiments, dummy panel 3055 can be made of glass and/or polymer layers, and appear substantially similar to an actual PV module. This can provide improved aesthetics in the column of PV modules. In embodiments, a slot between dummy panel and transition pan can include a screen to prevent large debris or bugs from entering the space between PV modules and PV pans.

In embodiments, PV modules are affixed to PV pans in a way that allows water or debris to flow under the PV module. Water and debris may enter through gaps between adjacent PV modules, as discussed above. As shown in FIG. 30D, debris or water can flow, as indicated by the arrows A, under adjacent PV modules 3001 in a space between PV modules and PV pans. Water and debris may exit out through lower transition pan 3005A positioned at an end of each column of PV module pan assemblies, as discussed above in relation to FIG. 30C. Water can flow down-roof both over the top of a column of PV modules and in a space between PV modules and PV module pans as noted above via the gaps G between adjacent PV modules. Water flowing in a space can drain over an eave flashing 3057 attached or integrated with a down-roof edge portion of the lower transition pan 3006A and off the roof.

As shown in FIG. 30E, gaps between adjacent PV modules 3001 also can allow for air to flow up-roof between PV modules and PV pans indicated by arrows B. The air can escape both through gaps between PV modules, the gap between PV modules and dummy modules, and at a top of the column through a ridge vent. This allows improved cooling of the PV modules, which in turn allows for more efficient electricity generation.

As shown in FIGS. 30F-I, in embodiments, a screen may be provided in gaps between adjacent PV modules. Screens allows for flow of air and water as discussed above in relation to FIGS. 30D and 30E. As shown, a screen, for example vented mesh 3058A or grating 3058B, can be positioned in the gap between the adjacent PV modules, and extend between standing seams on either side of the column of PV modules. Screens allow water and debris to flow into the space between PV modules and PV pans as noted above. In various embodiments, the size of the holes of the mesh and gratings can be sized to prevent large debris or bugs from entering the space. In various embodiments, mesh or grating may be provided with resiliency and provide similar benefits as sealing members discussed above.

In embodiments with water flowing between PV pan and PV modules, such as discussed above, openings 3051 can be made in sidewall portions of the PV pans 3020 to provide routing or pathways for east-west or column to column wiring, as shown in FIG. 30J. Plugs 3052 can be installed into openings 3051 and around wires 3053, to prevent water flow between adjacent columns. As illustrated in FIG. 30K, standoffs 3054, for example made of foam, can be provided to position connectors or wires off of bottom surfaces of PV pans. In embodiments, east-west wiring can be provided under upper transition pans positioned at up-roof end portions of each column adjacent a roof ridge as illustrated in FIG. 9M.

As noted above, in various embodiments, adhesive can be used to bond PV modules to PV pans. As shown in FIGS. 31A-C, in embodiments, the adhesive or pads securing PV module 3101 to PV pan 3120 can be configured to guide water and debris toward the outside edges of the PV pan. For example, adhesive or pads can be angled or sloped toward the outside edges in a chevron shape configuration. The adhesive between PV module and PV pan can guide or direct the water (e.g., debris) to the sides of the pan and into the corresponding gutters 3121. Gutters 3121 of adjacent PV pans 3120 can form a continuous path for water and debris to flow in a down-roof direction into drains 3397 of transition pans 3391, as is shown in FIG. 23E.

In embodiments, up-roof end of down-roof module may be positioned below down-roof end of up-roof module, as is shown in FIGS. 32A-D. As shown in embodiments of FIGS. 32A-D, adjacent PV modules 3201 may be separated by sealing member 3281. Sealing member 3281 may be similar to sealing members discussed above. Further, in embodiments edge portion or portions of the up-roof PV module can be provided with an insert or edge treatment, for example paint or edge tape. For example, edges can be painted black or otherwise matched to appear at least substantially similar to the PV module and/or pans. In embodiments, a reflective material, for example a tape with a mirror like coating, can be secured to the edge portion and angled in an appropriate position, for example downwards, toward a top or upper surface of the down-roof PV module such that it appears to be a continuous PV module (e.g., with no horizontal gaps, openings, or seams between modules) from the down-roof module to the up-roof module. In embodiments, PV module edges can be beveled or cut such that they are angled downward. Specialized paint or material can be used to help conceal the gaps, spaces or seams between PV modules. For example, Vantablack or other “super black” paint or materials can be secured to the edge of up-roof of down-roof PV modules. For example, as shown in FIG. 33, in embodiments, adjacent PV modules 3301 can include edge tape 3303 as noted above.

In embodiments, PV pans may include mechanical couplings, for example male and female fasteners. Mechanical couplings may be used ensure that adjacent PV pans are installed with proper spacing so that the PV modules attached to the PV pans have the ΔH and G needed to achieved infinity visual effect from desired angles, as discussed above.

From the foregoing, it will be appreciated that specific embodiments of the invention have been described herein for purposes of illustration, but that various modifications may be made without deviating from the spirit and scope of the various embodiments of the invention. Further, while various advantages associated with certain embodiments of the invention have been described above in the context of those embodiments, other embodiments may also exhibit such advantages, and not all embodiments need necessarily exhibit such advantages to fall within the scope of the invention. Accordingly, the invention is not limited, except as by the appended claims.

While the above description describes various embodiments of the invention and the best mode contemplated, regardless how detailed the above text, the invention can be practiced in many ways. Details of the system may vary considerably in its specific implementation, while still being encompassed by the present disclosure. As noted above, particular terminology used when describing certain features or aspects of the invention should not be taken to imply that the terminology is being redefined herein to be restricted to any specific characteristics, features, or aspects of the invention with which that terminology is associated. In general, the terms used in the following claims should not be construed to limit the invention to the specific examples disclosed in the specification, unless the above Detailed Description section explicitly defines such terms. Accordingly, the actual scope of the invention encompasses not only the disclosed examples, but also all equivalent ways of practicing or implementing the invention under the claims.

The teachings of the invention provided herein can be applied to other systems, not necessarily the system described above. The elements and acts of the various examples described above can be combined to provide further implementations of the invention. Some alternative implementations of the invention may include not only additional elements to those implementations noted above, but also may include fewer elements. Further any specific numbers noted herein are only examples, alternative implementations may employ differing values or ranges, and can accommodate various increments and gradients of values within and at the boundaries of such ranges.

References throughout the foregoing description to features, advantages, or similar language do not imply that all of the features and advantages that may be realized with the present technology should be or are in any single embodiment of the invention. Rather, language referring to the features and advantages is understood to mean that a specific feature, advantage, or characteristic described in connection with an embodiment is included in at least one embodiment of the present technology. Thus, discussion of the features and advantages, and similar language, throughout this specification may, but do not necessarily, refer to the same embodiment.

Furthermore, the described features, advantages, and characteristics of the present technology may be combined in any suitable manner in one or more embodiments. One skilled in the relevant art will recognize that the present technology can be practiced without one or more of the specific features or advantages of a particular embodiment. In other instances, additional features and advantages may be recognized in certain embodiments that may not be present in all embodiments of the present technology.

Any patents and applications and other references noted above, including any that may be listed in accompanying filing papers, are incorporated herein by reference. Aspects of the invention can be modified, if necessary, to employ the systems, functions, and concepts of the various references described above to provide yet further implementations of the invention.

Unless the context clearly requires otherwise, throughout the description and the claims, the words “comprise,” “comprising,” and the like are to be construed in an inclusive sense, as opposed to an exclusive or exhaustive sense; that is to say, in the sense of “including, but not limited to.” As used herein, the terms “connected,” “coupled,” or any variant thereof means any connection or coupling, either direct or indirect, between two or more elements; the coupling or connection between the elements can be physical, logical, or a combination thereof. Additionally, the words “herein,” “above,” “below,” and words of similar import, when used in this application, refer to this application as a whole and not to any particular portions of this application. Where the context permits, words in the above Detailed Description using the singular or plural number may also include the plural or singular number respectively. The word “or,” in reference to a list of two or more items, covers all of the following interpretations of the word: any of the items in the list, all of the items in the list, and any combination of the items in the list.

Although certain aspects of the invention are presented below in certain claim forms, the applicant contemplates the various aspects of the invention in any number of claim forms. Accordingly, the applicant reserves the right to pursue additional claims after filing this application to pursue such additional claim forms, in either this application or in a continuing application. 

The invention claimed is:
 1. A building integrated photovoltaic system comprising: a first photovoltaic module pan assembly, having a first up-roof end and a first down-roof end, wherein the first photovoltaic module pan assembly is configured to be positioned at a first location on a pitched roof surface with the first up-roof end oriented up-roof of the first down-roof end, the first photovoltaic module pan assembly including a first pan and a first photovoltaic module; a second photovoltaic module pan assembly, having a second up-roof end and a second down-roof end, configured to be positioned at a second location on the pitched roof surface up-roof from the first location with the second up-roof end oriented up-roof of the second down-roof end, the second photovoltaic module pan assembly including a second pan and a second photovoltaic module, wherein the first photovoltaic module is supported a first distance further above the pitched roof surface at the first up-roof end than at the first down-roof end, wherein the second photovoltaic module is supported a second distance further above the pitched roof surface at the second up-roof end than at the second down-roof end, wherein the first photovoltaic module and the second photovoltaic module are configured to be observable from a location below an eve of the pitched roof surface and above a plane of the pitched roof surface so that a seam between the second photovoltaic module at the second down-roof end and the first photovoltaic module at the first up-roof end is obscured to create a seamless appearance; wherein portions of the first up-roof end of the first photovoltaic module pan assembly and the second down-roof end of the second photovoltaic module pan assembly are overlapping; and wherein the first distance and the second distance are both less than a thickness of the first photovoltaic module and less than a thickness of the second photovoltaic module in order to create the seamless appearance.
 2. The building integrated photovoltaic system of claim 1, wherein the first photovoltaic module and the first pan are a unitary structure.
 3. The building integrated photovoltaic system of claim 1, wherein the first photovoltaic module includes a top surface, and wherein the first photovoltaic module does not include a frame that extends past the top surface at the first up-roof end of the first photovoltaic module in order to create the seamless appearance.
 4. The building integrated photovoltaic system of claim 1, wherein the first pan includes a top surface facing the first photovoltaic module, wherein the first photovoltaic module is supported above the top surface with pads, tape or adhesive between the first photovoltaic module and the top surface, and wherein the first photovoltaic module is supported a greater distance from the top surface at the first up-roof end than at the first down-roof end.
 5. The building integrated photovoltaic system of claim 1, wherein the first pan includes a top surface and a bottom surface, wherein the first pan further includes legs, at the first up-roof end, including a portion of the bottom surface, and wherein the legs are configured to support the top surface of the first pan at an angle relative to the pitched roof surface.
 6. The building integrated photovoltaic system of claim 1, further including a non-functioning imitation photovoltaic module positioned down-roof and adjacent to the first photovoltaic module pan assembly, and wherein an up-roof end of the non-functioning imitation photovoltaic module is supported further from the pitched roof surface than the first photovoltaic module at the first down-roof end in order to create the seamless appearance between the non-functioning imitation photovoltaic module and first photovoltaic module.
 7. The building integrated photovoltaic system of claim 1, wherein the second pan includes a mating tab at the second down-roof end, and wherein the mating tab contacts an underside of the first photovoltaic module at the first up-roof end.
 8. The building integrated photovoltaic system of claim 1, further including a resilient sealing member between and contacting the first photovoltaic module and the second photovoltaic module, wherein the resilient sealing member is configured to be obscured by the first photovoltaic module from the location below the eve of the pitched roof surface and above the plane of the pitched roof surface.
 9. The building integrated photovoltaic system of claim 1, wherein a space is defined between the first photovoltaic module and the first pan, wherein a gap is defined between the first photovoltaic module and the second photovoltaic module, and wherein the gap is configured to allow water to enter into the space and flow down-roof from the first up-roof end to the first down-roof end in the space.
 10. The building integrated photovoltaic system of claim 1, wherein the first photovoltaic module at the first up-roof end overlaps in a vertical direction with the second photovoltaic module at the second down-roof end.
 11. The building integrated photovoltaic system of claim 1, wherein the first pan forms a standing seam of a standing seam roof with an adjacent non-photovoltaic roof pan.
 12. The building integrated photovoltaic system of claim 1, wherein the first pan and the second pan both contact and form a standing seam of a standing seam roof with an adjacent non-photovoltaic roof pan.
 13. The building integrated photovoltaic system of claim 1, wherein the first pan includes a rib contacting and supporting the first photovoltaic module at the first up-roof end, and the second photovoltaic module abuts the rib. 